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REGENERATION AND TRANSFORMATION
OF
CASSAVA {MANIHOT ESCULENTA CRANTZ.)
Promotor: Professor Dr. Ir. E. Jacobsen
Hoogleraar in de plantenveredeling
Co-promotor: Dr. R.G.F. Visser
Universitair hoofddocent plantenveredeling
Eri Sofiari
REGENERATION AND TRANSFORMATION OF CASSAVA (MANIHOT
ESCULENTA CRANTZ.)
Proefschrift
ter verkrijging van de graad van
doctor in de landbouw- en milieuwetenschappen,
op gezag van de rector magnificus,
Dr. C.M. Karssen,
in het openbaar te verdedigen
op dinsdag 28 mei 1996
des namiddags om half twee in de Aula
van de Landbouwuniversiteit te Wageningen
c\1 <T\ IA
CIP-DATA KONINKLIJKE BIBLIOTHEEK DEN HAAG
Eri Sofiari
REGENERATION AND TRANSFORMATION OF CASSAVA (MANIHOT ESCVLENTA CRANTZ.) Thesis Wageningen Agricultural University -With references-With summary in English, Dutch, Indonesia and Arabic.
ISBN 90-5485-536-3
Bibliographic Abstract: This thesis describes different regeneration systems of cassava. In the first system the embryos were highly organized. The use of the auxins NAA and 2,4-D to induce this organized system of somatic embryogenesis were compared in several genotypes. Bombardment of organized tissues did not result in transformed plants and culture of protoplasts isolated from organized cultures did not result in plant regeneration. In the second system, so called friable embryogénie callus, the embryos are less organized. Protoplasts isolated from friable embryogénie callus regenerated into plants. Bombardment of this friable embryogénie callus with DNA of constructs containing the luciferase gene resulted in transformed tissue. Transgenic tissue was selected using luciferase activity. Transformed mature embryos were multiplied by the organized system of embryogenesis before they were allowed to develop into plants. The transformed nature of the plant was confirmed by PCR and Southern Blot Analysis.
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Theorems (Stellingen)
1. Friable embryogénie callus is more successful than somatic embryos as a source for
protoplasts which regenerate into plants (This thesis).
2. Development and selection of unorganized cells from organized tissue can probably reduce
the genotype dependency for transformation.
3. I admire protoplasts and their contents, particularly the nuclei, because they drag my mind
to apprehend the beginning of life (This thesis; Lackie and Dow (1995), Dictionary of Cell
Biology P:388).
4. There are many opportunities to integrate conventional and biotechnological approaches to
achieve the desired end product like resistance to cassava bacterial blight. (This thesis; Jacobsen
(1991), Biotechnological Innovations in Crop Improvement, P:38).
5. When a higher production of carbohydrates has to be achieved in marginal soils with
minimum tillage by peasant fanners, cassava is the best crop.
6. The lack of knowledge of the factors controlling somatic embryogenesis, the asynchrony of
somatic embryo development, and low true-to-type embryonic efficiency are responsible for its
reduced commercial application (This thesis; Pedroso and Pais (1995), Plant Cell Tissue and
Organ Culture 43:147-154).
7. Substitution of cassava flour by one third for the imported wheat flour can save to the extent
of U$ 150 million per year in Indonesia (FAO, 1993).
8. "It is forgotten that change could be for the better or the worse. Even more important than
change is the direction of change and our sense of right and wrong, of truth and falsehood, of
justice and injustice and a commitment to prefer right, truth and justice on their antithesis"
(Azzam, 1992).
9. "After life's fitful fever, he sleeps well" (William Shakespeare).
10. Unlike students, businessmen and extension workers who go abroad, mingle with others and
get a "cultural shock", diplomats do not experience this simply because they are insulated from
the local community (Adapted from Weaver (1987), The Advising Quarterly, P:6).
Stellingen behorende bij het proefschrift " Regeneration and transformation of cassava (Manihot
esculenta Crantz.)" door Eri Sofiari, in het openbaar te verdedigen op dinsdag 28 mei 1996, te
Wageningen.
CONTENTS
Page
List of abbreviations
Chapter 1. General introduction 1
Chapter 2. Comparison of NAA and 2,4-D induced somatic
embryogenesis in cassava 19
Chapter 3. The investigation of somatic embryos and leaves
as sources for protoplast culture in cassava 35
Chapter 4. Plant regeneration from protoplasts isolated
from friable embryogénie callus of cassava 55
Chapter 5. Production of transgenic cassava plants by particle
bombardment using luciferase activity as selection marker 70
Chapter 6. Comparison of germination of NAA and 2,4-D induced
somatic embryos of cassava 89
Chapter 7. General discussion 107
Summary 119
Samenvatting 123
Ringkasan (Indonesia) 127
Summary in Arabic 131
Curriculum vitae 135
Acknowledgement 136
LIST OF ABBREVIATIONS
2,4-D = 2,4-dichlorophenoxyacetic acid ABA = abscisic acid AARD = Agency for Agricultural Research and Development A.turn = Agrobacterium tumefaciens
bar = Basta-resistance gene
BAP = 6,-benzylaminopurine BM = basal medium CIAT = Centro Internacional de Agricultura Tropical CSE = cyclic somatic embryogenesis Dicamba = 3,6-dicloro-2-methoxybenzoic acid DNA = Deoxyribose nucleic acid EDTA = ethylenediamine-tetra-acetic acid. GD = Gresshoff and Doy GUS = ß-glucuronidase FDA = Fluorescein diacetate FEC = Friable Embryogénie Callus IAA = [3-indoly]acetic acid IBA = 4-[3-indoly]butyric acid UTA = International Institute of Tropical Agriculture IL = initial leaf expiants LM = leaf mesophyll LUC = luciferase ME = mature embryo NAA = a-napthaleneacetic acid NPT11 = neomycin phosphotransferase II PCV = Pack Cell Volume PE = Plating Efficiency PEG = poly ethylene glycol Pic = Picloram = 4-amino-3,5,6,-trichloropicolinic acid PP = protoplast(s) PSE = primary somatic embryogenesis SH = Schenk and Hildebrandt TDZ (thidiazuron) = N-phenyl-Nl(l,2,3 thiadiazolyl)urea Zea= Zeatin = 6-[4-hydroxy-3-methylbut-2-enylamino]purine
CHAPTER 1
GENERAL INTRODUCTION
Cassava in Indonesia
Cassava (Manihot esculenta Crantz) is known as 'ubi kayu' or 'singkong' in Indonesia. It is
grown particularly in rural areas, either as monocrop or intercrop. It is a low capital crop and
easy to grow even in the marginal land areas with minimum culture practices. Farmers will
choose cassava as a main crop if they do not have enough capital or if the physical environment
is not suitable for cultivating their land with other crops. However, cassava is a crop of ever
growing importance to Indonesia. It has an important role in the economy of rural areas in
Indonesia. A large proportion of the cassava production is for the starch-based industry and for
animal feed, the rest is for fresh human consumption (Damardjati et al., 1991). The use of
cassava will increase in Indonesia in the future due to several reasons, such as high demand for
animal feed and industrial purposes.
A general problem of cassava in Indonesia is its low production. Susceptibility to major pests
and diseases is a main reason. In wet regions like Western Java and Sumatra the problem of
Cassava Bacterial Blight is often very serious, while in dry areas red mite infections are a large
problem (Soenarjo et al., 1987). Two types of superior cassava cultivars are required. For
industrial purposes a plant is needed with high starch and dry matter content. A non-branching
growth habit is preferred for mechanized harvest. For fresh human consumption a low cyanide
content is favourable. Other common agronomical traits such as early harvestability, good root
shape and broad adaptation to various soils and climatic conditions have also become a major
concern in several breeding programmes (Damardjati, 1991; Soenarjo et al., 1987). To solve
the above mentioned problems breeding programmes, at the Central Research Institute for Food
Crops-Agency for Agricultural Research and Development, in Bogor, Indonesia were initiated.
Selection and crossing of advanced clones from a germplasm collection is the first possibility to
achieve these goals. A trend of significant changes of cassava utilization in Asia, due to the
international market development and domestic demand, will press the breeder to supply the best
cultivar/clone in a short time. To fulfil this goal, breeding programmes should not only rely on
conventional techniques, but they also need support from other techniques such as mass clonal
propagation and genetic modification. In this thesis the main interest was to develop a genetic
modification system.
The availability of a genetic modification system in cassava will have tremendous implications
for increasing the economic value of cassava products. To improve the quality of cassava,
particularly for the starch industry, genetic transformation is a prerequisite. Modification of
starch content and starch composition will also be beneficial for food industries, sweeteners in
drinks and for non-food applications like chemical industry (e.g. production of ethanol and
fructose), paper-board, textiles, cosmetics and pharmaceutical industry (Visser and Jacobsen,
1993). In recent years, in Indonesia food factories such as bakeries which utilize wheat flour in
large quantities have increased. If the ratio of amy lose to amylopectin of cassava starch can be
manipulated then the wheat flour for bread-making can be partly substituted with cassava flour.
This will lead to reduced wheat import and to increased income of the cassava farmer in
Indonesia.
Requirements for the development of genetic modification techniques
Three key components are required for developing a reliable genetic modification system. These
are: (1) the delivery of DNA into plant cells in such a way that cell damage is minimized to
enhance stable transgene integration into the recipient genome and to permit cell proliferation
leading to transformation events; (2) the availability of appropriate selectable markers, or
reporter genes which have no detrimental effects on metabolism and which are suitable to
multiply and isolate individual transformation events (for review see Wilmink and Dons, 1993);
(3) the development of a culture system where (transformed) cells are efficiently converted to
plants (DeBlock, 1993; McElroy and Brettell, 1994; Songstad et al., 1995). Over the past years
several transfer techniques of DNA to plant cells have been developed such as silicon fibers
(Kaeppler et al., 1990), intact tissue electroporation (DeKeyser et al., 1990), microinjection
(DeLaat and Blaas, 1987) and electrophoresis (Griesbach and Hammond, 1993). The most
commonly used and potentially-applicable ones are Agrobacterium-mediated gene delivery,
microprojectile/particle bombardment and protoplast electroporation (see Table 1 for some
examples).
Table 1. Selected examples of successful transformation systems in some plant species.
Species
Carthamus tinctorius Carrica papaya Cucumis sativus Nicotiana tabacum Solanum tuberosum Vitis vinifera
Oryza sativa
Triticum aestivum Zea mays
Expiants
cotyledons somatic embryos protoplasts protoplasts stems somatic and zygotic embryos protoplasts immature embryos protoplasts suspensions suspensions
Methods'
A.mm Pb Peg + El Peg + El A. turn Pb
El Pb Peg El Pb
Outcome'
st + r st + r tr + c st + r st + r st + r
st + r st + r st + r st + r st + r
Reporter gene Reference
nptll + gus nptll + gus cat + gus npdl + gus nptll nptll
gus gus gus + bar gus + bar nptll + bar
Orlikowska et al., 1995 Fitch et al., 1994 Wieczorek & Sanfacon, 1995 Spörlein and Koop, 1991 Visser étal., 1989 Scorzaet al., 1995
Shimamoto et al., 1993 Christou and Ford, 1995 Cornejoet al., 1993 He et al., 1994 Register et al., 1994
a: A.tum=A.tumefaciens, El=electroporation, Pb=particle bombardment, Peg=polyethylene glycol, b: c=callus, r=regenerated, st=stably transformed, tr=transient.
Gene transfer techniques
Agrobacterium-mediated transformation
The Agrobacterium tumefaciens DNA delivery system is the most commonly used technique. It
probably relates to the first invention of DNA delivery in plants by this method. Initially it was
limited to Kalanchoe and Solanaceae, particularly tobacco. Nowadays, the use of Agrobacterium-
mediated transformation has changed dramatically, it is possible to transform a wide range of
plants with a limitation in monocots (reviewed by Wordragen and Dons, 1992). Although
cassava is a host for Agrobacterium it has proven to be not highly amenable to it (Table 2).
Protoplast and electroporation-mediated transformation
In principle protoplasts are the most ideal expiants for DNA delivery. They can be cultured as
single cells that produce multicellular colonies from which plants develop. Plants derived from
protoplasts are generally clonal in origin. This provides a useful tool for any transformation
system, because it will eliminate chimerism in transgenic plants. The use of protoplasts is,
however, hampered by the regeneration system which is highly species dependent. For
transformation, protoplasts can be used in conjunction with PEG to alter the plasma membrane
which causes reversible permeabilization that enables the DNA to enter the cytoplasm as was
demonstrated, for example, in Lolium multiform (Potrykus et al., 1985) and Triticum
monococcum (Lörz et al., 1985). Another technique to increase the permeability of plasma
membranes and even cell walls to DNA is by electroporation (for review see Jones et al., 1987).
In this method electrical pulses enable the DNA to enter the cells. Rice was the first crop in
which fertile transgenic plants resulted from protoplast electroporation (Shimamoto et al., 1989).
Electroporation, like particle bombardment has the advantage that also intact tissues can be used
as target cells (Abdul-Baki et al., 1990; Dekeyser et al., 1990; McCabe et al., 1988). This
reduces the problem associated with regeneration to a minimum and provides the technology
applicable to a wider range of species. In cassava electroporation of tissue has so far not resulted
in stably transformed plants (Luong et al., 1995) (Table 2). A real bottle neck is regeneration
of protoplasts via callus into plants.
Table 2. Cassava transformation and its results (1985-1995)
Expiants
Leaf-discs Stem-discs of greenhouse various tissues of in vitro plants and somatic embryos Somatic embryos
Somatic embryos Somatic embryos
Protoplasts Somatic embryos Somatic embryos Axillary nodal buds Somatic embryos Embryogénie suspensions
Methods2
Pb
A.tum+Pb A. tum
A.tum+Pb A. turn
El A. turn A. turn Pb El Pb
Outcomeb
tr
partial trf partial trf
trf tr
tr partial trf tr tr tr tr
Reporter gene
gus
gus gus
gus+nptll gus+nptll+bar
gus gus+bar gus gus+nptll gus gus+nptll
References
Franche et al., 1991
Fauquetet al., 1993 Raemakers et al., 1993 Sarriaetal., 1995 Chavarriaga et al.,1993 Cabrai et al., 1993 Sarriaetal., 1995 Arias et al., 1995 Kommet al., 1995 Luong et al., 1995 Schöpke et al., 1995
a: A.tum=A.tumefaciens, el=electroporation, pb=particle bombardment; b: trf=transformed no information of regeneration; tr=transient; partial trf= transgenic plants are not obtained.
Microprojectile/particle bombardment-mediated transformation
The use of particle bombardment or biolistics to deliver foreign DNA provides an alternative
method in cassava transformation. Particle bombardment is the only procedure capable of
delivering DNA into cells almost in any tissue. Until a certain level this method will eliminate
genotype/species dependency and regeneration problems like they occur in protoplast-mediated
transformation. The first transgenic plant obtained by using this method was in tobacco (Klein
et al., 1989). Following this successful transformation method, particle bombardment is widely
used in plants which are less amenable to Agrobacterium infection, particularly monocots.
Improvement of several DNA delivery devices to accelerate the particle (microprojectile) has
resulted in the most recent model the Biolistic ™ PDS-1000 (Bio-Rad Laboratories, Richmond,
Ca). Those devices are available commercially, however the price is relatively high at present.
Tungsten or gold particles, coated with DNA, are commonly used as microprojectiles to deliver
DNA into the target tissue (recently reviewed by Songstad et al., 1995).
Selection and reporter genes used in genetic modifications
To be able to benefit transformed cells, the gene of interest is coupled to a selectable marker
gene. This marker gene is necessary to allow selective growth of transformed cells. Transformed
cells are benefited through selection procedures involving selectable-markers. Until recently they
were restricted to the expression of genes encoding resistance to antibiotics. Nowadays also
genes conferring resistance to herbicides are used (Thompson et al., 1987; Gordon-Kamm et al.,
1990).
A number of antibiotics and herbicides has been used as selective agent in plant transformation.
In cereals resistance to the herbicide phosphinothricin (PPT) was chosen for the selection of
transgenic plants (Cao et al., 1990). In Carica papaya (Fitch et al., 1994), Vitis vinifera
(Nakano et al., 1994; Scorza et al., 1995), maize (Rhodes et al., 1988) and rice (Chen et al.,
1987) the neomycin phosphotransferase (NPT11) gene, which confers resistance to kanamycin and
related antibiotics (Fraley et al., 1986), was used as a selectable marker.
Reporter genes are useful tools for the analysis of gene expression after a transformation event.
The most commonly used reporter genes to analyze transient and stable transformation are the
genes encoding ß-glucuronidase (GUS)(Janssen and Gardner, 1990), luciferase (Ow et al., 1986)
and anthocyanin (Ludwig et al. 1990). Every type of reporter gene has its own characteristics.
GUS is a reporter gene of which the expression is detected by destructing the tissue. The other
two reporter genes can be visualized without destroying the tissue.
Regeneration of cassava
True seeds of cassava have hardly been used for plant propagation by farmers because of its high
level of heterogeneity which is a result of genetic segregation. Conventional in vitro culture of
cassava is almost always accomplished by vegetative propagation of stem and bud cuttings. This
is categorized as non-adventitious shoot regeneration where existing meristems are allowed to
regenerate into plants.
For genetic modification techniques in cassava the availability of an adventitious regeneration
system (somatic embryogenesis, organogenesis) would be of great use. The first successful
attempts of organogenesis in cassava were reported by Tilquin (1979) and Shahin and Shepard
(1980). However, they were not repeatable by others. Plant regeneration by somatic
embryogenesis was first reported by Stamp and Henshaw (1982) and this has been repeated for
many cultivars by others as well (Raemakers et al., 1993a; Mathews et al., 1993; Szabados et
al., 1987; see also Table 2). Organogenesis is the process by which cells and tissues are forced
to undergo changes which lead to the production of unipolar structures, namely shoots or roots,
where the vascular system is often connected to the parental tissue (Thorpe, 1990). In contrast
somatic embryogenesis leads to the production of bipolar structures containing a root and shoot
axis and they develop completely separated from the maternal tissue (Emons, 1994). Somatic
embryogenesis may start spontaneously from one somatic cell (Hacius, 1978; Sharp et al., 1980;
Wann, 1988), although also a multicellular origin has been described (for review see Raemakers
etal., 1995).
Somatic embryogenesis
Somatic embryogenesis is the development of embryos from somatic cells via a systematic series
of characteristic morphological stages. The structure of somatic embryos resembles that of
zygotic embryos, (see for reviews: Ammirato, 1983; Zimmerman, 1993 and Raemakers et al.,
1995). Somatic embryogenesis proceeds either through direct or indirect induction of
regeneration (Carman, 1990; Sharp et al., 1980; Wann, 1988; William and Maheswaran, 1986).
In direct somatic embryogenesis, the embryos form without an intervening phase of callus
growth, while in indirect embryogenesis a callus phase precedes the formation of embryos
(Ammirato, 1983). The somatic cells that give rise to embryogenesis are called embryogénie
cells. In principle every living cell has totipotency though only a limited number of cells from
expiants, regenerating protoplasts, or suspensions eventually give structures that exhibit
embryogenesis. The frequency of cells that actually give rise to somatic embryos in carrot
suspension cultures was not more than 2 % (De Jong et al., 1993). The expression of cells
competent to regeneration, rely on the tissue culture environment, such as hormone balance,
sugars, amino acids, salt concentrations and physical environment (William and Maheswaran
1986; Nuti Ronchi, 1981; Vasil and Vasil, 1986; Franklin and Dixon, 1994). The methods to
find the appropriate conditions for somatic embryogenesis are still the main concern in
regeneration research.
In the first report on successful regeneration of cassava plants by somatic embryogenesis a two-
step procedure was used (Stamp and Henshaw, 1982; Stamp and Henshaw, 1987). In the first
step (induction medium of embryos) leaves or zygotic embryos were cultured on medium with
a high concentration of 2,4D enabling direct embryogenesis. In step 2 a low concentration of
2,4D was needed for further development of the embryo. Recent improvements of somatic
embryogenesis included the use of different types of auxins like Dicamba and Picloram
(Sudarmonowati and Henshaw, 1993), the development of cyclic somatic embryogenesis
(Raemakers et al., 1993b) improved methods for germination of somatic embryos (Mathews et
al., 1993) and suspension culture (Taylor et al., 1995). Especially the last mentioned system has
provided possibilities for the development of a transformation protocol in cassava.
Protoplast culture
Regenerated plants from protoplasts have been reported in many important crops. In the 80's
rice was an example of plant regeneration from protoplasts (Abdullah et al., 1986). Nowadays
procedures have been developed for the regeneration of plants from isolated protoplasts of
potato, wheat, tomato, soybean, cabbage, chicory, lettuce, butterbean, winged bean, cucumber,
pea, orchids, citrus, kiwifruit, strawberry, cotton, and some tree species (for reviews see Bajaj,
1989a; 1989b; 1993a; 1993b).
The use of protoplasts in plant transformation requires at least three stages: protoplast isolation,
the transfer of genes into the protoplasts and regeneration of transformed protoplasts into
functional plants (Gallun et al., 1976). Theoretically protoplasts can be isolated almost from any
part of the plant. However, the possibility to isolate protoplasts capable of sustained division and
plant regeneration is still restricted to a limited number of plant species and expiant sources
(Blackhall et al., 1994). Leaf mesophyll is frequently employed as source material for protoplast
isolation. Other expiants used for protoplast isolation are hypocotyl, stem, petiole, cotyledon,
florets, callus, suspensions and somatic embryos (Blackhall et al., 1994; Atree et al., 1989).
However, sustained division leading to plant regeneration is not routine for most of the cell type
sources from protoplasts of many monocotyledonous species. For that reason, embryogénie cell
suspension cultures provide the most commonly used sources for protoplasts in cereals.
Protocols for regeneration of transgenic plants from protoplasts of rice are available (Toriyami,
et al., 1988; Shimamoto et al., 1989; Davey et al., 1991) and research in this direction for other
crops is still on going. These studies mainly are focused on practical applications, involving
protoplasts of a wide range of species. Especially for plants which are not amenable to
Agrobacterium-medmted transformation, protoplast transformation has proven to be a valuable
tool to obtain stable transformants (Simpson and Estrella, 1989; De Block, 1993). From these
studies it has become clear that many variable factors play a role in the regeneration of stably
transformed plants when using protoplasts in combination with direct gene transfer (Schweiger
et al., 1993; Lurquin, 1989, De Block, 1993; Fowke and Cutler, 1994).
Generally, three principal factors which govern the regeneration competence of protoplasts are
the plant genotype, ontogenetic state of the expiant source and the cultural environment. The
latter includes medium composition and growth conditions (Blackhall et al., 1994).
Friable embryogénie callus
The most recent regeneration system of cassava is by the use of friable embryogénie callus. By
culturing somatic embryogénie tissue on Gresshoff and Doy (1972) basal medium instead of
Murashige and Skoog basal medium (1962) friable embryogénie callus could be obtained (Taylor
et al., 1995). For enhanced proliferation, the friable embryogénie callus was cultured in liquid
Schenk and Hildebrandt (1972) medium as a kind of embryogénie suspension. Morphologically,
friable embryogénie callus is composed of globular embryoids varying in size from 50-100 /tm
in diameter. The origin of the globular embryoids has been confirmed from one or a few cells
at the surface of the older units. Maturation of friable embryogénie callus into normal somatic
embryos has been accomplished although the rate of maturation of embryos is very low (Taylor
et al., 1995). High levels of transient expression of the GUS gene were established using friable
embryogénie callus as the target tissue for particle bombardment (Schöpke et al. 1995).
From the studies described so far, it is obvious that only appropriate regeneration systems will
be amenable to transformation. Therefore, the choice of a regeneration system holds an
important role in establishing the transformation of cassava. So far the existing regeneration
systems have been combined with all the available methods of transformation (see Table 2), but
without success. The establishment of a regeneration system which can be used for transforma
tion is a very important task to be able to improve specific traits in cassava.
Outline of the thesis
In this thesis several strategies were studied to find a method for transformation of cassava. In
Chapter 2, the effect of several auxins and expiant densities on cyclic somatic embryogenesis
is described. Improvements of somatic embryogenesis were based on the comparison with
existing methods. The relevant aspects of somatic embryogenesis for cassava transformation are
10
also discussed in Chapter 2. In Chapter 3 the use of cyclic embryos as a source of protoplasts
is described. The possibilities and limitations of protoplast culture as an alternative tool for gene
transformation are also discussed. The friable embryogénie callus (FEC) system is introduced
in Chapter 4 and it is shown that protoplasts of this tissue regenerate into plants. By combining
the protoplast regeneration system with transformation the possibility to obtain stably
transformed cassava plants is discussed in this Chapter. In Chapter 5 the friable embryogénie
callus was successfully used as target tissue for particle bombardment. The transformed nature
of the plants was confirmed by Southern blot analysis. In Chapter 6 germination of embryos
induced by the new protocol of somatic embryogenesis described in Chapter 2, is investigated
using the desiccation method from Mathews et al.(1993). This improved germination protocol
is of importance for the germination of transgenic embryos. In Chapter 7 a general discussion
is given.
11
REFERENCES.
Abdul-Baki, A.A., Saunders, J.A., Mathews, B.F., and Pittareli, G.W. 1990. DNA uptake during electroporation of germinating pollen grains. Plant Sei. 70:181-190.
Abdullah, R., Cocking, E.C. and Thompson, J.A., 1986. Efficient plant regeneration from rice protoplasts through somatic embryogenesis. Bio/Technology 4:1087-1090.
Ammirato, P.V. 1983. The regulation of somatic development in plant cell cultures: suspension culture techniques and hormone requirements. Bio/Technology 1:68-74.
Arias-Garzón D.I., Sarria R. 1995. New Agrobacterium tumefaciens plasmids for cassava transformation. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:245-251.
Atree, S.M., Dunstan, D.I., and Fowke, L.C. 1989. Initiation of embryogénie callus and suspension cultures, and improved embryo regeneration from protoplasts, of white spruce (Picea glauca) Can.J.Bot. 67:1790-1795.
Bajaj, Y.P.S. 1989a. Plant protoplasts and genetic engineering 1. In: Biotechnology in Agriculture and Forestry Vol 8. Springer-Verlag, Berlin. P:444.
Bajaj, Y.P.S. 1989b. Plant protoplasts and genetic engineering 11. In: Biotechnology in Agriculture and Forestry Vol 9. Springer-Verlag, Berlin. P:499.
Bajaj, Y.P.S. 1993a. Plant protoplasts and genetic engineering 111. In: Biotechnology in Agriculture and Forestry Vol 22. Springer-Verlag, Berlin. P:332.
Bajaj, Y.P.S. 1993b. Plant protoplasts and genetic engineering IV. In: Biotechnology in Agriculture and Forestry Vol 23. Springer-Verlag, Berlin. P:390.
Blackhall, N.W., Davey, M.R., and Power J.B. 1994. Isolation, culture, and regeneration of protoplasts. In: Plant Cell Culture. A Practical Approach. Second Edition. Dixon, R.A and Gonzales, R.A. (Eds). Oxford University Press. Oxford, New York, Tokyo. P:27-39.
Cabrai G.B., Aragâo F.J.L., Monte-Neshich D.C., and Rech E.L. 1993. Transient gene expression in cassava protoplasts. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings CBN. First International Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P: 244-247.
Cao, J., Duan, X., McElroy, D., and Wu, R. 1990. Regeneration of herbicide resistant transgenic rice plants following microprojectile-mediated transformation of suspension culture cells. Plant Cell Rep. 11 : 586-591.
Carman, J.G. 1990. Embryogénie cells in plant tissue cultures: occurrence and behaviour. In Vitro Cellular Developmental Biology 26:746-753.
12
Chavarriaga-Aguirre, P., SchöpkeC, Sangare, A., FauquetC, andBeachy, R.N. 1993. Transformation of cassava embryogénie tissue using Agrobacterium tumefaciens. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings CBN. First International Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P: 222-225.
Chen, W.H., Gartland, K.M.A., Davey, M.R., Sotak, R., Gartland, J.S., Mulligan, B.J., Power, J.B., and Cocking, E.C. 1987. Transformation of sugarcane protoplasts by direct uptake of a selectable chimeric gene. Plant Cell Rep. 6:297-301.
Christou, P., and Ford, T.L., 1995. Parameters influencing stable transformation of rice immature embryos and recovery of transgenic plants using electric discharge particle acceleration. Annals of Bot. 75:401-413.
Cornejo, M.J., Luth, D., Blankenship, K.M., Andersonn, O.D., and Blechl, A.E. 1993. Activity of a maize ubiquitin promoter in transgenic rice. Plant Mol. Biol. 23:567-581.
Damardjati, D.S., Widowati, S., and Dimyati, A. 1991. Cassava processing and utilization in Indonesia. CIAT. Cassava Newsletter 15 (2): 1-5.
Davey, M.R., Kothari, S.L., Zhang, H., Rech, H.L., Cocking, E.C. and Lynch, P.T. 1991. Transgenic rice: characterization of protoplast-derived plants and their seed progeny. J. of Exp. Bot. 42 (242): 1159-1169.
De Block, M. 1993. The cell biology of plant transformation: Current state, problems, prospects and implications for plant breeding. Euphytica 71: 1-14.
De Jong, A.J., Schmidt, E.D.L., and De Vries, S.C. 1993. Early events in higher plant embryogenesis. Plant Mol. Biol. 22: 367-377.
De Keyser R.A., Claes, B., De Rycke, R.M.U., Habet, M.E., Van Montagu, M.C., and Caplan, A.B. 1990. Transient gene expression in intact and organized rice tissue. Plant Cell 2:591-602.
DeLaat, A., and Blaas, J., 1987. An improved method for protoplast microinjection suitable for transfer of entire plant chromosomes. Plant Sei 50:161-169.
Emons, A.M.C. 1994. Somatic embryogenesis: cell biological aspects. Acta Bot. Neerl. 43(1): 1-14.
Fauquet, CM. , Schöpke, C , Chavarriaga, P., Sangare, A., and Beachy, R.N. 1993. Genetic engineering technologies to control viruses and their application to cassava viruses. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings CBN. First International Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P: 190-207.
Fitch, M.M.M., Pang, S.Z., Slightom, Lius. S., Tennant, P., Manshardt, R.M., and Gonsalves, D. 1994. Genetic transformation in Carica papaya (Papaya). In: Bajaj (Eds). Biotechnology in Agriculture and Forestry Vol 29, Plant protoplasts and genetic engineering V. Springer-Verlag, Berlin. P:237-255.
Fowke, L.C., and Cutler, A.J. 1994. Plant Protoplast Techniques. In: Harris, N., and Oparka, K.J.
13
(Eds). Plant Cell Biology. A Practical Approach. IRL Press. Oxford University Press, New York. P: 177-197.
Fraley R.T., Rogers S.G., and Horsch, R.B. 1986. Genetic transformation in higher plants. CRC Critical reviews in Plant Sciences 4(1): 1-46.
Franche, C , Bogusz, D., Schópke, C , Fauquet, C , and Beachy, R.N. 1991. Transient gene expression in cassava using high-velocity microprojectiles. Plant Mol. Biol. 17:493-498.
Franklin, C.I., and Dixon, R.A. 1994. Initiation and maintenance of callus and cell suspension cultures. In:Dixon, R.A and Gonzales, R.A. (Eds). Plant Cell Culture. A Practical Approach. Second Edition. IRL Press. Oxford University Press. P:l-22.
Gallun, E., Aviv, D., Vardi, A., and Zelcer, A. 1976. Protoplasts in studies of cell genetics and morphogenesis. In: Brz, W., Reinhard, E., and Zenk, M.H. (Eds). Plant Tissue Culture and Its Bio-technological Application. Proceedings of the First International Congress on Medicinal Plant Research, Section B. University of Munich, Germany. Springer-Verlag Berlin Heidelberg New York. P:303-312.
Gordon-Kamm, W.J., Spencer, T.M., Mangano, M.R., Adams, T.R., Daines, R.J., William, G.S., O'Brien, J.V., Chambers, S.A. Adams, Jr. W.R., Willetts, N.G., Rice, T.B., Mackey C.J., Krueger, R.G., Kausch, A.P., and Lemaux P.G. 1990. Transformation of maize cells and regeneration of fertile transgenic plants. The Plant Cell. 2:603-618.
Gresshoff, P.M., and Doy, C.H. 1974. Development and differentiation of haploid Lycopersicon esculentum (tomato). Planta 107:161-170.
Griesbach, R.J., and Hammond, J. 1993. Incorporation of the GUS gene into orchids via embryo electrophoresis. Acta. Hort. 336:165-169.
Hacius, B. 1978. Question of unicellular origin of non-zygotic embryos in callus cultures. Phytomorpho-logy28: 74-81.
He, D.G., Mouradov, A., Yang, Y.M., Mouradova, E., and Scott, K.J. 1994. Transformation of wheat (Triticum aestivum) through electroporation of protoplasts. Plant Cell Rep. 14: 192-196.
Janssen, B.J., and Gardner, R.C. 1990. Localized transient expression of GUS in leaf discs following cocultivation with Agrobacterium. Plant Mol. Biol. 14: 61-72.
Jones H., Tempelaar M.J., and Jones, M.G.K. 1987. Recent advances in plant electroporation. Oxford Surveys of Plant Mol. and Cell Biol. 4:347-357.
Kaeppler, H.F., Gu, W., Somres, D.A., Rines, H.W., Cockburn, A.F. 1990. Silicon carbide fiber-mediated DNA delivery into plant cells. Plant Cell Rep. 8:415-418.
Klein T.M., Kornstein L., Sanfords J.C., and Fromm M.E. 1989. Genetic transformation of maize cells by particle bombardment. Plant Physiol. 91:440-444.
14
Konan N.K., Sangwan R.S., and Sangwan-Norrell. 1995. Nodal axillary meristems as target tissue for shoot production and genetic transformation in cassava (Manihot esculenta Crantz). The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:276-288.
Lorz, H., Baker, B., and Schell, J. 1985. Gene transfer to cereal cells mediated by protoplast transformation. Mol. Gen. Genetic 199: 178-182.
Ludwig, S.R., Bowen, B., Beach, L., and Wessler, S. R. 1990. A regulatory gene as a novel visible marker for maize transformation. Science 247:449-450.
Luong, H.T., Shewry, P.R., and Lazzeri, P.A. 1995. transient gene expression in cassava somatic embryos by tissue electroporation. Plant Science 107: 105-115.
Lurquin, P.F. 1989. Uptake and integration of exogenous DNA in plants. In: Bajaj, Y.P.S. (Eds). Plant protoplasts and genetic engineering 11. Biotechnology in Agriculture and Forestry Vol 9. Springer-Verlag, Berlin. P:55-73.
Mathews, H., Schöpke, C , Carcamo, R., Chavarriaga, P., Fauquet, C , and Beachy, R.N. 1993. Improvement of somatic embryogenesis and plant recovery in cassava. Plant Cell Rep. 12:328-333.
McCabe, D. E., Swain, W.F., Martinell, B.J., and Christou, P. 1988. Stable transformation of soybean (Glycine max) by particle acceleration. Bio/Technology 6:923-926.
McElroy, D., andBrettell, R.I.S. 1994. Foreign gene expression in transgenic cereals. Tibtech, 12:62-68.
Nakano, M., Hoshino, Y., and Mil, M. 1994. Regeneration of transgenic plants of grapevine (Vitis vinifera L.) via Agrobacterium rhizogenesis-mediated transformation of embryogénie calli. J. of Exp. Bot. 45 (274):649-656.
Nuti-Ronchi, V. 1981. Histological studies of organogenesis in vitro from callus cultures of two Nicotiana species. Can. J. Bot. 59:1969-1977.
Orlikowska, T.K., Harwood, J.C., and William, E.D. 1995. Factors influencing Agrobacterium tumefaciens-mediated transformation and regeneration of the safflower cultivar 'centennial'. Plant Cell Tissue and Organ Culture 40:85-91.
Ow, D.W., Wood, K.V., DeLuca, M., De Wet, J.R., Helinski, D.R., and Howell, S.H. 1986. Transient and stable expression of the firefly luciferase gene in plant cells and transgenic plants. Science 234:856-859.
Potrykus, I., Saul, M., Paskowski, J., and Shillito, R.D. 1985. Direct gene transfer into protoplasts of a graminaceous monocot. Mol. Gen.Genet. 199:183-188.
Raemakers , C.J.J.M., Jacobsen, E., and Visser R.G.F. 1993. Somatic embryogenesis and transformation of cassava. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings CBN. First International Scientific Meeting of the Cassava Biotechnology Network. Cartagena. Colombia 25-28 August 1992. P: 208-215.
15
Raemakers, C.J.J.M., Bessembinder, J., Staritsky, G., Jacobsen, E., and Visser, R.G.F. 1993a. Induction, germination and shoot development of somatic embryos. Plant Cell Tissue and Organ Culture. 33:151-156.
Raemakers, C.J.J.M., Amati, M., Staritsky, G., Jacobsen, E., and Visser, R.G.F. 1993b. Cyclic somatic embryogenesis and plant regeneration in cassava. Annals of Bot. 71:289-294.
Raemakers , C.J.J.M., Jacobsen, E., and Visser R.G.F. 1995. Secondary somatic embryogenesis and application in plant breeding. Euphytica. 81:93-107.
Register, J.C., Peterson D.J., Bell, P.J., Bulock, W.P., Evan, I.J., Frame, B., Greenland, A.J., Higgs, N.S., Jepson, I., Jiao, S.P., Lewnau, C.J., Silick, J.M., and Wilson, H.M. 1994. Structure and function of selectable and non-selectable transgenes in maize after introduction by particle bombardment. Plant Mol. Biol. 25 (6): 951-961.
Rhodes, CA. , Pierce, D.A., Metler, I.J., Mascarenhas, D., and Detmer, J.J. 1988. Genetically transformed maize plants from protoplasts. Science 240:204-207.
Sarria, R., Torres, E., Balcâzar, N., Destéfano-Beltrân, L., and Roca, W.M. 1995. Agrobacterium-mediated transformation of cassava. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:241-244.
Schöpke, C , Muller, L.E., and Kohlenbach, H.W. 1987. Somatic embryogenesis and regeneration of plantlets in protoplast cultures from somatic embryos of coffee (Coffea canephora P ex Fr.). Plant Cell Tissue and Organ Culture 8:243-248.
Schweiger, H.G., Dirk, J., Koop, H.U., Kranz, E., Neuhaus, G., Spangenberg, G., and Wolff, D. 1987. Individual selection, culture and manipulation of higher plant cells. Theor. Appl. Genet. 73:769-783.
Scorza, R., Cordts, J.M., Ramming, D.W., and Emershad, R.L. 1995. Transformation of grape (Vitis vinifera L.) zygotic-derived somatic embryos and regeneration of transgenic plants. Plant Cell Rep. 14:589-592.
Shahin, E.A., and Shepard, J.F. 1980. Cassava mesophyll protoplasts: isolation, proliferation and shoot formation. Plant Science Letters 17:459-465.
Sharp, W.R., Sohndahl, M.R., Evans, A.E., Caldas, L.S., and Maraffa, S.B. 1980. The physiology of in vitro asexual embryogenesis. Horticultural Reviews 2:268-310.
Schenk, R.U., and Hildebrandt, A.C. 1972. Medium and techniques for induction and growth of monocotyledonous and dicotyledonous plant cell cultures. Can. J.Bot. 50:99.
Shimamoto, K., Terada, R., Izawa, T., and Fujimoto, H. 1989. Fertile transgenic rice plants regenerated from transformed protoplasts. Nature 338:274-276.
Simpson, J., and Estrella, L.H. 1989. DNA recombination and transformation of agricultural crops. In: Bajaj, Y.P.S. (Eds). Plant protoplasts and genetic engineering 11. Biotechnology in Agriculture and
16
Forestry Vol 9. Springer-Verlag, Berlin. P:75-97.
Soenarjo, R., Poespodarsono, S., and Nugroho, J. H. 1987. Cassava Breeding and Agronomy Research in Asia. Proceeding of Regional Workshop Held in Rayong, Thailand, Oct.26-26, 1987. P:27-33.
Songstad, D.D., Somers, D.A., and Griesbach, R.J. 1995. Advances in alternative DNA delivery techniques. Plant Cell Tissue and Organ Culture 40:1-15.
Spörlein, B., and Koop, H.U. 1991. Lipofectin: direct gene transfer to higher plants using cationic liposomes. Theor. Appl. Genet. 83:1-55.
Stamp, J. A. and Henshaw, G.G. 1982. Somatic embryogenesis in cassava. Zeitschrift für Pflanzenphysiologie 105:183-187.
Stamp, J.A. and Henshaw, G.G., 1987. Secondary somatic embryogenesis and plant regeneration in cassava. Plant Cell Tissue and Organ Culture 10:227-233.
Sudarmonowati. E., and Henshaw, G.G. 1993. The induction of somatic embryogenesis of recalcitrant cultivars using picloram and dicamba. Proceedings CBN. First Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P: 128-133.
Szabados, L., Hoyos, R., and Roca, W. 1987. In vitro somatic embryogenesis and plant regeneration of cassava. Plant Cell Rep. 6:2248-251.
Taylor, N.J., Edwards, M., and Henshaw, G.G. 1995. Production of friable embryogénie calli and suspension culture system in two genotypes of cassava. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:229-240.
Thorpe, T. A. 1990. The current status of plant tissue culture. In: Bhojwani S.S. (Eds). Plant Tissue Culture: Applications and Limitations. Elsevier Science Publ. Amsterdam, P: 1-33.
Thompson, J.C., Mowa, N.R., Tizard, R., Crameri, R., Davies, J.E., Lauwereys, M., and Botterman, J. 1987. Characterization of the herbicide-resistance gene bar from Streptomyces hy gros copieus. The EMBO J.6 (9):2519-2523.
Tilquin, J.P., 1979. Plant regeneration from stem callus of cassava. Can. J. Bot. 57:1761-1763.
Toriyama, K., Arimoto, Y., Uchimiya, H., and Hinata, K. Transgenic rice plants after direct gene transfer into protoplasts. Bio/Technology 6:1072-1074.
Vasil, I.K., and Vasil, V. 1986. Regeneration in cereals and others grass species. In: Vasil, I.K. (Eds) Cell culture and somatic cell genetics of plants. Vol. 3. Plant regeneration and genetic variability. Academic Press, Orlando, P: 121-150.
Visser, R.G.F., Jacobsen, E., Witholt, B., and Feenstra, W.J. 1989. Efficient transformation of potato {Solanum tuberosum L.) using a binary vector in Agrobacterium rhizogenes. Theor. Appl. Genet. 78:594-600.
17
Visser, R.G.F., and Jacobsen, E. 1993. Towards modifying plants for altered starch content and composition. Tibtech. 11:63-68.
Wann, S.R. 1988. Somatic embryogenesis in woody species. Horticultural reviews 10:153-181.
Wieczorek, A., and Sanfaçon, H. 1995. An improved method for the generation and transfection of protoplasts from Cucumis sativa cotyledons. Plant Cell Rep. 14:603-610.
William, E. G., and Maheswaran, G. 1986. Somatic embryogenesis: factors influencing coordinated behaviour of cells as an embryogénie group. Annals of Bot. 57:443-462.
Wilmink, A., and Dons, H.J.M. 1993. Selective agents and marker genes for use in transformation of monocotyledonous plants. Plant Mol. Biol. Reporter 11:165-185.
Wordragen M.F., and Dons, H.J.M. 1992. Agrobacterium tumefaciens mediated transformation of recalcitrant crops. Plant Mol. Biol. Reporter 10:12-36.
Zimmerman, J.L., 1993. Somatic embryogenesis: A model for early development in higher plants. The Plant Cell 5: 1411-1423.
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CHAPTER 2
COMPARISON OF NAA AND 2,4-D INDUCED SOMATIC EMBRYOGENESIS IN CASSAVA
E. Sofiari, E. Kanju, C.J.J.M. Raemakers, E. Jacobsen, R.G.F. Visser.
ABSTRACT
The two auxins NAA and 2,4-D were compared in their ability to induce somatic embryogenesis in cassava. In 6 genotypes primary somatic embryos were induced from leaf expiants cultured on 2,4-D supplemented medium. NAA was not effective for this process. Both NAA and 2,4-D were capable of inducing secondary or cyclic somatic embryogenesis. In all 6 genotypes a higher number of somatic embryos was formed in NAA than in 2,4-D containing medium. Furthermore, the time period to become mature was shorter in NAA than in 2,4-D. In NAA the highest number of embryos was formed if the embryos were subcultured every 15 days, in the procedure with 2,4-D this was 20 days. High density culture in NAA did not result into the formation of embryos, whereas in 2,4-D it leads to the formation of globular embryos. In 2,4-D the newly induced embryos were connected vertically to the expiant and in most cases they did not possess a closed root pole. In NAA the embryos were connected horizontally to the expiant and the embryos possessed a closed root pole. In some genotypes, repeated subculture of embryos in NAA, resulted in a gradual shift from somatic embryogenesis to adventitious root formation. This shift could be reversed by subculture of the material in 2,4-D.
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INTRODUCTION
Cassava (Manihot esculenta Crantz) is after rice, sugar cane and maize the fourth most important
crop grown in the tropical areas as a dietary source of carbohydrates for human consumption,
animal feed and starch industry. Cassava is cheaper in economic terms than many other crops
(Cock, 1985). Cassava has further as advantage that it can be grown in marginal areas where
there are major constraints for the production of other root crops and grains (Byrne, 1984;
Lynam, 1993). Drawbacks for the further utilization of cassava are the low protein content of
the roots, the presence of toxic levels of cyanogenic glucosides in the roots and rapid
deterioration of roots after harvest. Because cassava is propagated by cuttings derived from
stems of plants in the field, diseases and pests are easily transmitted. Large scale multiplication
of healthy genotypes will reduce the yield losses caused by diseases and pests. Genetic modifica
tion could be used in those cases where there is no genetic variation available for a trait in the
gene pool of cassava by introducing genes with the desired trait from other species.
For these applications regeneration methods should be available. In cassava the only routine
method of regeneration is somatic embryogenesis. In cassava, somatic embryogenesis starts with
the induction of primary embryos from zygotic embryos (Stamp and Henshaw, 1982) or leaves
(Stamp and Henshaw, 1987a, Szabados et al., 1987, Mathews at al., 1993, Raemakers et al.,
1993a). The primary somatic embryos can be used as source of expiants to initiate a new cycle
of embryogenesis (Stamp and Henshaw, 1987b; Raemakers et al. 1993b,c, Mathews et al.,
1993). This phenomenon has been described as secondary somatic embryogenesis. It is
associated with loss of integrated group control of organized cells. Some cells act independently,
break away from group control and initiate a new cycle of somatic embryos (Williams and
Maheswaran, 1986). Cyclic somatic embryogenesis is attractive for mass production of clonal
plantlets since the multiplication rates generally exceeds those attainable with other tissue culture
regeneration systems, like shoot micropropagation. In Junglans regia (McGranahan et al. 1988)
and in Glycine max (McCabe et al., 1988) secondary somatic embryogenesis has been used
successfully to obtain transformed plants. 2,4-D is the most commonly used auxin for induction
of primary and secondary somatic embryogenesis in cassava. The characteristics of somatic
embryogenesis initiated by 2,4-D have several disadvantages for use in either mass propagation
20
or genetic modification. For use in mass propagation it is important that the system of
embryogenesis should be as simple as possible and the embryos should mature readily and
develop into plants. Optimal for plant transformation would be a single epidermal cell origin.
In cassava, the embryos originate from groups of cells. This group consists of either mesophyllic
cells only or mesophyllic plus epidermal cells (Stamp, 1987; Raemakers et al., 1996). In Glycine
max it was shown that the origin of embryos induced by NAA differed from embryos induced
by 2,4-D (Hartweck et al., 1988). In Cucurbita pepo NAA induced embryos matured more
easily than 2,4-D induced embryos (Jelaska et al., 1985). In this report the effect of the auxin
NAA on somatic embryogenesis is compared with 2,4-D in several cassava genotypes.
MATERIAL AND METHODS
Plant Material
The cultivars MCol.22 and MCol.1505 (CIAT, Cali, Columbia), TMS90853 (UTA, Nigeria),
Gading, Adira 1 and Adira 4 (kindly provided by Dr. A. Dimyati, AARD-Indonesia) were used
in this study. Nodal in vitro cuttings (2-3 cm long) were cultured on basal medium (BM)
supplemented with 8 g/1 Daichin agar. BM consisted of Murashige and Skoog salts and vitamins
(1962), and 20 g/1 sucrose. The pH was adjusted to 5.7 before autoclaving.
The temperature in the growth chamber was 30° C, the photoperiod 12 hours and the irradiance
40 jiimolV1.
Influence of auxins on primary somatic embryogenesis
After 20 days of growth young leaf lobes (0.5-1.0 mm) were isolated from the sprouted nodal
expiants and cultured in light on solid BM supplemented with 1-8 mg/1 2,4-D or 0.1-40 mg/1
NAA (step 1). After 20 days the expiants were transferred to BM supplemented with 0.1 mg/1
BAP (step 2). Forty leaf expiants were cultured per treatment. Embryo induction and
maturation was evaluated after respectively 15 and 40 days.
21
Influence of auxins on secondary somatic embryogenesis
A new cycle of somatic embryogenesis was started by culturing 0.2 g. of chopped mature
embryos (0.25-0.50 mm2) in 300 ml flasks with 75 ml of BM supplemented with 1-8 mg/12,4-D
or 0.1-40 mg/1 NAA. After 20 days the 2,4-D cultured expiants were transferred to BM
supplemented with 0.1 mg/1 BAP. A new cycle of embryogenesis was started after 20 (NAA)
or 30 (2,4-D) days. The jars were cultured in light on an orbital shaker (LAB-Line Instruments
Inc. Model 3519) at 120 rpm. The experiments were set up as a factorial, completely
randomized design with four replications. The number of mature embryos was counted and the
presence and morphology of roots was recorded. A mature embryo was defined as an embryo
with fully developed, green cotyledons with a clear hypocotyl.
Influence of subculture duration on secondary somatic embryogenesis
The optimal concentration of NAA and 2,4-D respectively 10 mg/1 and 8 mg/1 (see 2.3) was
chosen to determine the influence of the length of an embryo cycle on the number of embryos
produced. Ten to 30 days after the start of a new cycle of embryogenesis, embryos of Adira 4
were chopped again and 0.2 g was subcultured in the same medium. The experiment was set up
as a factorial, completely randomized design with three replications. The number of mature
embryos was counted.
Influence of expiant density on secondary somatic embryogenesis
Somatic embryos of Adira 4, subcultured every 15 days in liquid BM supplemented with 10 mg/1
NAA or every 20 days in BM supplemented with 8 mg/1 2,4-D, were used to study the effect
of expiant density. A new cycle of embryogenesis was started by culturing 0.1 to 1.5 g of chop
ped embryos of Adira 4 in 200 ml flasks with 60 ml of BM supplemented with 10 mg/1 NAA
or 8 mg/1 2,4-D. The experiment was set up as a factorial, completely randomized design with
four replications. The number of mature embryos per flask (ME) was counted. The number of
ME per flask divided by the density (g/flask) gives the number of ME per gram (ME/g). The
total biomass was recorded, divided into mature embryos, immature embryos, and non-
embryogenic callus. Immature embryos were defined as embryos from globular to the torpedo-
shaped stage.
22
Histology of secondary somatic embryogenesis
Mature embryos were slightly fragmented and cultured on solid BM supplemented with 10 mg/1
NAA. After 14 days of culture expiants were fixed in glutaraldehyde (5%) for at least 2 hours,
before dehydrating in a series of alcohol solutions (50, 70, 90 and 100 %) for 30 minutes. After
dehydration clearing of the expiants was done by keeping them in solutions with different
concentrations of infiltration solution and absolute alcohol (3:1, 1:1, 1:3, 1:0, and 1:0) for 2
hours. The expiants were then embedded in Technovit 7100 on blocks and after hardening secti
ons of 6 ßm in width were made using a Reichart-Jung 2050 Supercut microtome. Sections were
mounted on glass slides and stained with Toluidine Blue. Photographs were taken with a Carl
Zeiss bright field Axiophot photomicroscope (model number 7082).
RESULTS
Influence of auxin type on primary embryogenesis
Leaf expiants cultured on NAA or 2,4-D formed callus which appeared after 4 days of culture.
On NAA the callus was soft. Somatic embryos or embryo-like structures were not formed.
Instead, all expiants formed abundantly adventitious roots. On 2,4-D two types of callus were
observed: soft and compact. The soft callus never produced embryos or roots. Depending on the
genotype the compact callus had a yellowish or white colour. Parts of this compact callus was
organized in embryo-like structures or globular embryos. Genotypic differences were not
apparent in the formation of compact callus. After transfer to step 2 medium mature embryos
were formed in all genotypes (Table 1).
Mature embryos appeared after 2-3 weeks, except in Adira 1 where it took 8 weeks. The highest
number of mature embryos was found on a medium supplemented with 8 mg/12,4-D. Genotypic
differences were present. Adira 1 gave the lowest numbers of mature embryos and MCol.22 the
highest number (Table 1). On a medium supplemented with 8 mg/1 2,4-D this was respectively
0.2 mature embryos per initial leaf explant (ME/IL) and 4.8 ME/IL.
23
Table 1. The effect of 2,4-D on the formation of mature somatic embryos per cultured leaf expiant (40 leaf expiants were cultured per treatment).
2,4-D (mg/1)
1 2 4 8
TMS90853
_ --0.6
Adira 1
0.0 0.1 0.1 0.2
Adira 4
0.1 a 0.2 a 0.5 ab 1.5 b
MCol.1505
0.1 a 0.2 a 0.7 ab 1.5 b
MCol.22
0.1 a 0.2 a 2.0 b 4.8 c
Gading
0.4 a 0.2 a 0.4 a 1.7 a
Note: mean value followed by the same letter in a column denotes no significant difference by LSD (0.05) test.
Influence of auxins on secondary somatic embryogenesis
Time to become mature and number of mature embryos formed
In all tested genotypes NAA and 2,4-D induces secondary somatic embryogenesis (Table 2). In
10 mg/1 NAA torpedo shaped embryos were already visible after 6 days of culture, and after 14
days most of the embryos were mature. The mean weight of a mature embryo varied between
11 and 92 mg. In 2,4-D the first torpedo shaped embryos were visible after 20 days. For further
maturation these embryos were cultured for another 10 days in liquid step 2 medium. After that
maturation phase the mean fresh weight per embryo varied between 5 mg and 26 mg. Because
of this difference in the development NAA and 2,4-D induced embryos were subcultured for a
new cycle of embryogenesis, respectively, after 20 and 30 days. In this way embryos of all
tested genotypes were maintained for three months on 10 mg/1 NAA. In Table 2 the results of
a population of embryos subcultured for at least three months in NAA is given and compared
with 2,4-D. Both auxins at a concentration of 0.1 mg/1 did not result in mature embryos (data
not shown). At a concentration of 1 mg/1 2,4-D only a few were formed (data not shown),
whereas with 1 mg/1 NAA there was a significant increase in the number of embryos produced.
The highest number of embryos was formed with 8 mg/1 2,4-D and 10 mg/1 NAA. In all
genotypes more embryos were formed in NAA than in 2,4-D. Higher concentrations of both
auxins reduced significantly the number of embryos produced.
24
Root Formation
NAA induced embryos formed roots after several subcultures in NAA. 2,4-D induced embryos
never formed roots, even not after 2 years of continuous subculture. The formation of roots was
dependent on the genotype and the NAA concentration. TMS90853 and Adira 1 had the highest
percentage root formation. In MCol.1505 it was observed in maximum 18% of the mature
embryos. In Adira 4 and MCol.22 root formation never occurred and in Gading it was observed
occasionally. At 4 and 10 mg/1 NAA the highest percentages of embryos had formed roots. It
declined with increasing concentrations of NAA. In first instance the roots formed were clearly
tap roots and it was not correlated with a decrease in the number of mature embryos. After
continued subculture of TMS90853 and Adira 1 embryos in NAA the nature of the roots shifted
Table 2. Effect of NAA and 2,4D on the number of mature embryos and the percentage of embryos with roots (between brackets).
Concentrât- —
Genotype
ion (mg/l) TMS90853 Adira 1 Adira4 MCol.22 MCol.1505 Gading
NAA: 1 4 10 20 30 40 2,4-D: 4 8 32
59b(42d) 213c(70e) 360d(23c) 64b(13b) 17a(0a) 9a(0a)
100b(0a) 162c(0a) 14a(0a)
53abc(13a) 123d(47b) 292e(35b) 83bc(5a) 26ab(0a) 8a(0a)
74a(0) 123b(0) 22a(0)
45a(0) 126c(0) 323d(0) 89b(0) 60a(0) 13a(0)
38a(0) 119b(0) 85b(0)
34a(0) 108ab(0) 268c(0) 143b(0) 44a(0) 17a(0)
99b(0) 187c(0) 28a(0)
22a(6ab) 74b(13b) 376d(18bc) 91b(2a) 38ab(Oa) 5a(0a)
108b(0) 148c(0) 13a(0)
327(5)
151(0)
Mean value followed by the same letter in a column (for auxins separately) denotes no significant difference by LSD (0.05) test; 4 replications, per replication 0.20 gam/flask.
to adventitious roots. This phenomenon was not observed in the other genotypes. The
adventitious roots grew long and slender, while the taproots were thick and short. The adventi
tious roots developed from callus and were associated with a decrease in the number of embryos
formed. Root formation was not dependent on the developmental stage at which embryos were
used to start a new cycle of embryogenesis. Rooted NAA cultures could be made embryogénie
25
again by subculture in 2,4-D. Already after one cycle in 2,4-D only embryos without roots were
formed. If that one cycle in 2,4-D was followed by subculture in NAA than in the next 1 to 2
cycles embryos without roots were formed followed by embryos with taproots which after
continuous subculture shifted to adventitious roots.
Influence of time of subculture
The amount of embryos produced was dependent on the subculture regime. The main
characteristics are in all genotypes the same and in Table 3 these are given with Adira 4 as
example.
Table 3: Influence of subculture duration on formation of the number of new embryos.
Genotype
Adira 4
Auxin
10 mg/1 NAA 8 mg/1 2,4-D
10
830 b 65 b
duration 15
801 b 30 a
in days 20
788 b 120 c
30
207 a 79 b
Mean value followed by the same letter in one line denotes no significant difference by LSD (0.05) test, 4 replications, per replication 0.20 gam/flask.
A shorter subculture duration resulted in starting material which consisted of less developed
embryos. Embryos cultured in 2,4-D for 10 days were globular shaped and those cultured for
30 days were mature. Embryos cultured for 10 days in NAA were almost mature with light
green cotyledons and if cultured for 30 days the embryos were mature with darkgreen
cotyledons. The previously used subculture regime of 20 days for NAA was not optimal. In
NAA the highest number of embryos was produced if embryos were subcultured for 10 days.
For 2,4-D the optimal subculture duration was 20 days. In 2,4-D a relatively large fraction of
embryos were single embryos whereas in NAA almost all embryos were multiple embryo
clusters. The above described characteristics of different subculture regimes in NAA and 2,4-D
were also observed in the other genotypes. In Adira 4 all tested subculture durations gave a
higher yield of mature embryos in NAA than in 2,4-D. In other genotypes NAA gave a higher
yield from 10-20 days whereas with 30 days 2,4-D outyielded NAA (results not shown). In the
26
following experiments embryos in NAA were subcultured after 15 days and in 2,4-D after 20
days.
The effect of expiant density
The amount of embryos used to start a new cycle of somatic embryogenesis had different effects
in NAA and 2,4-D. These effects are shown using Adira 4 as example. In Figs. 1A and B the
number of mature embryos (ME) formed is given. It is expressed as number of ME per flask
(ME/flask). The number of ME/flask divided by the density (g/flask) gives the number of ME
per gram (ME/g). With NAA the number of ME/flask increases up to a density of 0.8 g/flask
with 2489 ME (Fig. 1 A). Than it decreases to 207 ME/flask at a density of 1.5 g/flask. For 2,4-
D the optimal density is 0.2 g/flask with 186 ME. At a density higher than 0.8 g/flask no mature
embryos were formed. If converted to ME/g than in both NAA (Fig. 1A) and 2,4D (Fig. IB)
containing medium the highest number of ME/g is formed at a density of 0.1 g/flask. In Figs.
1C and D the total biomass produced per flask is given. With NAA containing medium a density
of 0.1 g/flask produced 11.1 g and 89% of the biomass were mature embryos, 5% immature
embryos and 6% callus (Fig. 1C). In NAA the amount of biomass production was relatively
constant over a density of 0.1 to 1.5 g/flask. At a density of 1.5 g/flask only 14% of the
embryos were mature embryos. At this density most of the biomass (58%) was callus. In 2,4-D
there is a significant increase in biomass with increasing densities (Fig. ID). Furthermore, there
is a shift from mature embryos at the lower densities to immature embryos at the higher
densities. The percentage callus is relatively constant. The mass of immature embryos consisted
almost completely of globular embryos. Small amounts of these masses were cultured on solid
step 2 medium for maturation. It was found that at a density of 1.5 g NAA has the potential to
produce 3000 mature embryos.
Histology of NAA induced embryos.
NAA induced embryos differed from 2,4-D induced embryos in the way they were attached to
the expiant. In 2,4-D, the shoot pole points vertically upwards and the root pole was not visible
since it was embedded in expiant tissue (Raemakers et al., 1996). In NAA the shoot-root pole
axis of the embryo was almost horizontal to the expiant. The broader side of the embryo was
27
the shoot pole and the more narrow the root pole. In Fig. 3A longitudinal and in Figs 3B and
3C transversal sections are shown. The transversal sections are from the same two embryos: Fig.
3B is from near the shoot pole and Fig 3C from near the root pole. The embryos seem to lie on
the epidermis. Near the shoot and root pole the embryo was connected to the expiant by a thin
layer of cells.
28
ß g g g «embryos/gram
S £ 4000
a îooo
mature smb B䣣ä immature emb E 2 2 3 < I mature emb s emb t2Z£d callus
Figure 1: Influence of explant density in 10 mg/1 NAA (A) and 8 mg/1 2,4-D (B) on the production of mature embryos and on the fresh weight production in 10 mg/1 NAA (C) and 8 mg/1 2,4-D (D).
29
Figure 3. Longitudinal (A) and transverse sections (B, C) of NAA induced embryos (after 15 days of culture).
30
DISCUSSION
Somatic embryogenesis offers promises for rapid multiplication and plant transformation. For
both applications somatic embryogenesis starts with the induction of primary embryos. In
cassava NAA does not initiate primary somatic embryogenesis. 2,4-D has that capability and all
cassava genotypes tested responded with the formation of mature embryos. Also in Bambusa
oldhamii 2,4-D has the capacity to induce primary embryogenesis and NAA not. Chang, 1991).
However, in Pisum sativum (Ozcan et al., 1993), and Arachis hypogeae (Ozias-Akins, 1989)
NAA is more efficient than 2,4-D in inducing primary somatic embryogenesis. All cassava
genotypes formed secondary somatic embryos in a much higher frequency than primary
embryos. The usefulness of secondary somatic embryogenesis for plant multiplication is depen
dent on several variables. One of them is the time period for embryos to become mature and the
number of embryos produced. In NAA an embryogénie cycle leading to mature embryos is
finished in 14 days compared to 30 days in 2,4-D. Also in Cucurbita pepo (Jelaska, 1980) it was
found that NAA induced embryos maturated more easily than 2,4-D induced embryos. In all
genotypes NAA was initially superior for a high production of mature embryos. However, after
several cycles in NAA there is, in some genotypes, a shift from embryogenesis to adventitious
rooting. This shift was also observed in some genotypes of Pisum sativum (Ozcan et al., 1993)
and Glycine max (Mante et al., 1989). In other genotypes of Pisum sativum (Ozcan et al., 1993)
and Glycine max (Lazzeri et al., 1987) and in Cucurbita pepo (Jelaska, 1980) NAA induced
embryos have an higher capacity to germinate into normal plants than 2,4-D induced embryos.
Also in cassava germination of 2,4-D induced embryos is poor and a slow process. In Chapter
6 the germination ability of NAA induced embryos will be compared with 2,4-D induced
embryos.
For transformation it is beneficial to have regeneration of single epidermal cells. In 2,4-D the
embryos are formed from groups of cells which originate from internal tissue (Stamp, 1986;
Raemakers et al., 1995). Bombardment of 2,4-D induced embryos led to the recovery of
chimeric embryos. The chimeric sector was restricted to the epidermis with as a result that these
31
transformed cells could not be transferred to a new cycle of embryos (results not shown),
because the new embryos initiated from deeper cell layers. The NAA induced embryos differed
in the way they were attached to the expiant. This suggests a different origin. Unfortunately, the
histological data of NAA induced embryos gave no evidence for single epidermal cell origin.
Bombardment of NAA induced embryos resulted in transient GUS activity of the same level as
2,4-D induced embryos and also with NAA medium the transformed sector of an embryo could
not be increased (data not shown). Two other observations might be of importance with respect
to transformation. One is the fact that in 2,4-D also globular embryos could be multiplied and
the other is that high density culture in 2,4-D leads to the production of large numbers of
globular embryos. Maybe a further reduction of the subculture period, combined with high
density culture will result in more friable cultures. In such cultures it is more likely that either
the embryos originate from single epidermal cells or that they originate from multiple cells but
that the epidermis divides anticlinal to contribute to deeper cell layers. Bombardment of such
cultures might lead to chimeric transformed embryos of which the transformed sector also
encompasses deeper cell layers.
32
REFERENCES
Byrne D., 1984. Breeding Cassava. In: Janick, J. (Eds). Plant breeding reviews, Vol 2 . AVI, Westport CT, USA. P: 73-113.
Chang, W.C. 1991. Bamboos.In: Bajaj Y.P.S. (Eds), Biotechnology in Agriculture and Forestry Vol 16. Springer-Verlag, Berlin, P:211-237.
Cock, J.H., 1985. Cassava: new potential for a neglected crop. Wetview Press, Boulder and London. P:191.
Hartweck, L.M., Lazzeri, P.A., Cui, D., Collins, G.B., and Williams, E.G., 1988. Auxin-orientation effects on somatic embryogenesis from immature soybean cotyledons. In Vit. Cel. & Dev. Biol. 24:821-828.
Jelaska, S., Magnus, V., Seretin, M., and Lacan, G. 1985. Induction of embryogénie callus in Cucurbita pepo hypocotyl expiants by indole-3-ethanol and its sugar conjugates. Physiol. Plant. 64:237-242.
Lazzeri, P.A., Hildebrandt, D.F., and Collins G.B. 1987. Soybean somatic embryogenesis: effect of hormones and culture manipulations. Plant Cell Tissue and Organ Culture. 10:197-208.
Lynam, J. 1993. Potential impact of biotechnology on cassava production in the third world. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings CBN. First International Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P: 22-30.
Mante, S., Scorza., R., and Cordts, J., 1989. A simple, rapid protocol for adventitious shoot development from mature cotyledons of Glycine max cv Bragg. In Vitro Cell. Dev. Biol. 25:385-388.
Mathews, H., Schöpke, C , Carcamo, R., Chavarriaga, P., Schöpke, C.P., Fauquet, C , and Beachy, R.N., 1993. Improvement of somatic embryogenesis and plant recovery in cassava. Plant Cell Rep. 12:328-333.
McCabe, D.E., Swain, W.F., Martinelli, B.J., Christou, P. 1988. Stable transformation of soybean {Glycine maxfoy particle acceleration. Bio/Technology 6:923-926.
McGranahan, G.H., Leslie, CA., Uratsu, S.L., Martin, L.A., and Dandeker, A.M. 1988. Agrobacterium-mediated transformation of walnut somatic embryos and regeneration of transgenic plants. Bio/technology 6:800-804.
Murashige, T., and Skoog, F. 1962. A revised medium for rapid growth and bioassay with tobacco cultures. Physiologum Plantarum. 15:473-497.
Ozias-Akins, P. 1989. Plant regeneration from immature embryos of peanut. Plant Cell Rep. 8:217-218.
Özcan, S., Barghchi, M., Firek, S., and Draper, J. 1993. Efficient adventitious shoot regeneration and somatic embryogenesis in pea. Plant Cell Tissue and Organ Culture 34:271-277.
33
Raemakers, C.J.J.M., Bessembinder, J., Staritsky, G., Jacobsen, E., and Visser, R.G.F. 1993a. Induction, germination and shoot development of somatic embryos in cassava. Plant Cell Tissue and Organ Culture 33:151-156.
Raemakers, C.J.J.M., Amati, M , Staritsky, G., Jacobsen, E., and Visser, R.G.F. 1993b. Cyclic somatic embryogenesis and plant regeneration in cassava. Annals of Bot. 71:289-294.
Raemakers, C.J.J.M., Schavemaker, CM., Jacobsen, E., and Visser, R.G.F. 1993c. Improvements of cyclic somatic embryogenesis of cassava (Manihot esculenta Crantz). Plant Cell Rep. 12:226-229.
Raemakers, C.J.J.M., Jacobsen, E., and Visser, R.G.F. 1995. Histology of somatic embryogenesis and evaluation of somaclonal variation. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:276-288.
Stamp, J.A., and Henshaw, G.G. 1982. Somatic embryogenesis in cassava. Zeitschrift für Pflanzenphysiologie. 105:183-187.
Stamp, J. A. 1987. Somatic embryogenesis in cassava: the anatomy and morphology of the regeneration process. Annals of Bot. 59: 451-459.
Stamp, J.A., and Henshaw, G.G. 1987a. Somatic embryogenesis from clonal leaf tissue of cassava. Annals of Bot. 59:445-450.
Stamp, J. A., and Henshaw, G.G. 1987b. Secondary somatic embryogenesis and plant regeneration in cassava. Plant Cell Tissue and Organ Culture 10:227-233.
Williams, E.G., and Maheswaran, G. 1986. Somatic embryogenesis: factors influencing coordinated behaviour of cells as an embryogénie group. Annals of Bot. 57:443-462.
34
CHAPTER 3
THE INVESTIGATION OF SOMATIC EMBRYOS AND LEAVES AS SOURCES FOR
PROTOPLAST CULTURE IN CASSAVA
E. Sofiari, J.E.M. Bergervoet, C.J.J.M. Raemakers, E.Jacobsen, R.G.F. Visser.
ABSTRACT
While regeneration of cassava from protoplasts is still very difficult, it remains an important possibility for transformation. Therefore more basic knowledge about protoplast culture in cassava is needed. A mixture of the cell wall degrading enzymes cellulase RS Onozuka, macerozyme and pectolyase gave the highest yield of protoplasts irrespective of the tissue source. Protoplasts isolated from somatic embryos and leaf mesophyll from genotypes Adira 1, Adira 4, Gading, TMS90853, Line 11, MCol.22 and MCol.1505 were cultured in different media. A density of 2 x 105 protoplasts/ml plated in agarose drops gave the highest plating efficiency. Cell divisions and green calli were easily obtained from protoplasts isolated of both tissue sources. Root formation occasionally occurred but shoots were not observed.
35
INTRODUCTION
Cassava, Manihot esculenta Crantz, belongs to the family Euphorbiaceae. It is grown in a broad
range of soils and climatic conditions in the tropics. Cassava is originally a crop of the tropical
lowlands, but in the Andes of South America and the highlands of East Africa it is cultivated
at 2000 meter or more above sea level, where the average temperature may be as low as 17°C
(Jennings and Hershey, 1985). Because of its ability to survive under many types of stress such
as soil acidity, drought, low soil phosphorus and low ambient temperature cassava has become
an important crop in the tropical areas. Compared to other tuber crops and cereals, cassava is
very efficient in producing carbohydrates (Cock, 1985). Since conventional breeding of cassava
is hampered due to its heterozygosity, low fertility, poor seed set and low seed germination
(Jennings and Hershey, 1985) biotechnological methods such as somatic hybridization and
genetic transformation via protoplasts might play an additional role in its future improvement.
Because protoplasts are single cells without cell walls, they are excellent recipients for
macromolecules such as DNA (Shimamoto et al., 1989). Therefore, intensive studies to
regenerate plants from protoplasts have been performed in many plant species. This resulted in
plant regeneration from protoplasts in different species like Solanum tuberosum (Shepard et al.,
1977) and Mentha piperita (Sato et al., 1993). However, Manihot esculenta seems to be still
recalcitrant for protoplast regeneration. In literature there is only one successful report on
protoplast regeneration (Shahin and Shepard, 1980). Until now, no one has been able to repeat
this observation despite a number of different unpublished and unsuccessful experiments. Young
leaves of cassava were successfully used as starting material for inducing somatic embryos (
Stamp and Henshaw, 1987, Szabados et al., 1987; Mathews at al., 1993, Raemakers, 1993).
Because of the stagnation of protoplast regeneration in cassava, alternative sources of protoplasts
should be investigated other than young leaf material. Somatic embryogenesis in cassava is a
reliable system, so that it is worthwhile to be tested as an alternative source of protoplasts.
Somatic embryos apparently originate from embryogénie groups of cells within adaxial leaf
expiants (Stamp, 1987). In these somatic embryos, the place of embryogénie cells was suggested
36
to be present at a distance of two to five cell layers from the epidermis (Raemakers et al., 1995).
In sorghum (Wernicke and Brettell, 1980), pea (Mroginski and Kartha, 1981), and leek
(Buiteveld et al., 1993) it was indicated that the competence of such cells declined as they
differentiated into organized tissues. It is also assumed that in cassava the embryogénie cells in
somatic embryos are relatively more frequently competent than in young leaf lobes.
Genotype dependence for the ability to produce protoplasts has been reported in many crops
including cassava, showing that some genotypes are more amenable, whereas others are more
recalcitrant (Shepard et al., 1980; Radke and Grun, 1986). In other recalcitrant species such as
Cqffea canephora (Schöpke et al., (1987), Citrus mitis (Sim et al., 1988), Picea glauca (Attree
et al., 1989), and Oryza sativa (Shimamoto et al., 1989) it was shown that only protoplasts of
embryogénie tissue have the capacity to develop into plants. In this study somatic embryos and
leaf mesophyll of several genotypes were investigated as a protoplast source with the aim to
develop a protoplast based regeneration system.
MATERIALS AND METHODS
Plant material and growth conditions
The cultivars used were Adira 1, Adira 4 and Gading from Indonesia (kindly provided by Dr.
A. Dimyati, Indonesia (AARD), MCol.22 and MCol. 1505 from Columbia (CIAT); the genotype
TMS90853 from Nigeria (UTA) and Line 11 from Zimbabwe. First expanded leaves together
with the apical bud from in vitro grown shoots and mature somatic embryos (green cotyledons
and a distinct hypocotyl) were used for the isolation of protoplasts. Shoots were maintained by
regular subculture of nodal cuttings on a medium supplemented with Murashige and Skoog
(1962) salts and vitamins (MS), 7 g/1 Daichin agar and 20 g/1 sucrose. Somatic embryos were
induced from leaf expiants and maintained by cyclic somatic embryogenesis as described by
Raemakers et al. (1993). Shoots and somatic embryos were incubated in a growth chamber with
a day/night temperature of 30/28 ° C, a daylength of 12 hours and a light intensity of 40 /imolm" 2s ' . Protoplasts were cultured in the same environment unless stated otherwise.
37
Isolation of protoplasts
Prior to tissue plasmolysis and cell wall digestion, the plant materials were stored for 6 hours
in the dark, at 4° C. Then, 2 g of harvested leaves was sliced into small strips ( 1 - 2 mm) and
placed in Petri dishes (0 9 cm) containing 10 ml of cell wall digestion solution. Cell wall
digestion solution consisted of a mixture of enzymes (Cellulase RS Onozuka 10 g/1, Macerozyme
200 mg/1, Pectolyase 10 mg/1); growth regulators (NAA 1 mg/1, 2,4-D 1 mg/1, Zeatin 1 mg/1);
major salts ( 368 mg/1 CaCl2; 34 mg/1 KH2P04; 740 mg/KN03; 492 mg/1 MgSo4.7H20); minor
salts (19.2 mg/1 Na-EDTA; 14 mg/1 FeS04.7H20) and osmoticum (91 g/1 D-mannitol) and 0.5
g/1 MES. These incubation media are indicated by an "e" followed by a number; for example
"e5". After 18 h of incubation, 10 ml of washing medium was added to the solution. Washing
medium with an osmolarity 0.530 mOsm/kg consisted of major salts (see cell wall digestion
solution), 45.5 g/1 mannitol and 7.3 g/1 NaCl. The digested tissue was filtered through a 73 pM
pore size filter (PA 55/34 Nybolt - Switzerland) into a 250 ml beaker glass. The filtrate was
divided equally over two 12 ml conical screw cap tubes, and centrifuged at 600 rpm for 3 min
(Mistral 2000). The washing procedure was repeated once after removal of the supernatant. The
protoplast solution was resuspended by floating on 9.5 ml solution containing major and minor
salts (see cell wall digestion solution) and 105 g/1 sucrose. The pH was 5.8 and the osmolarity
0.650 mOsm. The solution with protoplasts was allowed to equilibrate for 5 minutes before 0.5
ml of washing medium was gently added on the top. After centrifugation at 700 rpm for 15 min
(Mistral 2000), the protoplasts were concentrated in a band between the sucrose and washing
medium. The protoplast layer was harvested with a pasteur pipette and the yield was counted
in a standard haemocytometer chamber.
Protoplast culture
Four protoplast densities (1x105, 2x10 5, 4x105, 6x105 pp/ml) were tested. Protoplast viability
was tested by using a Fluorescein diacetate (FDA) staining technique according to Widholm
(1972). Plating efficiency was defined as the number of protoplasts that had undergone the
second mitotic division according to Anthony et al. (1994). Observations on protoplast growth
were done daily until day 10. On the basis of the plating efficiency 2 x 10 5 pp/ml was chosen
for further experiments. Protoplasts were plated in Sea Plaque agarose 0.2 % w/v, disc type
38
culture (Dons and Bouwer, 1986) in pétri dishes (<j> 9 cm) containing 10 ml of medium A. The
Petri dishes were sealed with parafilm. Medium A (medium for cell division and micro callus
induction) consisted of MS salts and vitamins, 4.5 g/1 myo-inositol, 4.55 g/1 mannitol, 3.8 g/1
xylitol, 4.55 g/1 sorbitol, 0.098 g/1 MES, 40 mg/1 adeninsulphate and 150 mg/1 casein-
hydro ly sate, 0.5 mg/1 d-calcium-panthotenate, 0.1 mg/1 choline-chloride, 0.5 mg/ ascorbic acid,
2.5 mg/1 nicotinic acid, 1 mg/1 pyridoxine-HCl, 10 mg/1 thiamine-HCl, 0.5 mg/1 folic acid, 0.05
mg/1 biotine, 0.5 mg/1 glycine, 0.1 mg/1 L-cysteine and 0.25 mg/1 riboflavine. Glucose (59.40
g/1) or sucrose (36.03 g/1) were used as carbohydrate sources. The cultures were incubated in
the dark for 6 days after which they were adapted gradually to the standard light conditions.
Micro-callus culture
After 10 days the agarose droplets with small micro-calli were fragmented and cultured in Petri
dishes (4> 9 cm) containing solid medium for callus induction (medium B). Medium B consisted
of MS (salts and vitamins) solidified with 7 g/1 agar (Daichin), 54 g/1 D-mannitol, 2.5 g/1
glucose, 0.098 g/1 MES supplemented with 0.1 mg/12,4-D or 0.1 mg/1 NAA and 0.5 BAP mg/1.
Micro-calli were kept under diffuse light (25 /xmolnrV1) for 5-7 days before they were grown
in standard light intensity (40 /jmolm'V). Every 3 - 4 weeks pale-white or creamy calli were
transferred to fresh medium B. After two weeks of culture micro-calli were transferred to
medium C for callus development and regeneration. Medium C contained MS, salts and
vitamins, 7 g/1 agar (Daichin) supplemented with (0.01-1 mg/1) IAA, or (0.01-1 mg/1) NAA,
or 2 mg/1 2,4-D and 10 mg/1 Zeatin, or 0.1 mg/1 TDZ, or 0.1-10 mg/1 BAP, and 0.3 mg/1 GA
and vitamins at B5. After 4 and 8 weeks of culture in medium C, calli were evaluated for their
colour : white (translucent/pale white/creamy), green (light green, green) and brown; and for
their morphological appearance: friable or compact. Green calli were transferred individually
to media with different combinations of plant growth regulators to induce regeneration of shoots
(medium D) or to fresh medium C for long term storage. Twenty-five individual calli were
grown in a Petri dish (4> 9 cm) containing medium D. After 4 and 8 weeks calli were evaluated
for their development.
39
RESULTS
Protoplast yield
In pilot experiments different enzyme mixtures were tested on leaves (LM) and somatic embryos
(SE) of the genotype MCol. 1505 (Table 1). Protoplasts could be isolated easily from both
sources. In both type of expiants the enzyme mixtures e4 and e6 (cellulase RS Onozuka,
macerozyme and pectolyase) yielded the highest amount of protoplasts. The other enzyme
mixtures gave a significantly lower yield.
Table 1. The influence of different enzyme mixtures on the protoplast yield (10 5/gram) of leaves and somatic embryos of genotype MCol. 1505.
No. Enzyme mixture (%) leaf somatic embryos
el Cel.RS (1)/Mac (0.02) e2 Cel.R 10 (1)/Mac (0.02)/Pec. (0.001) e3 Cel.RS (1)/Mac (0.02)/ Dri(0.02) e4 Cel.RS (1)/Mac (0.02)/Pec (0.001) e5 Cel.RlO (10/Mac (0.02)/Dri (0.02) e6 Cel.RS On.(l) /Mac (0.02)/Pec (0.01) e7 Cel.RS On.(l)/Mac (0.01)/Pec (0.01) e8 Cel.RS (1)/Mac (0.01)/Dri (0.02)
Note: The mean value followed by the same letter denotes no significant differences according to Duncan Multiple Range (0.05) test. Cel.RS=Cellulase RS; Cel.R10=Cellulase R 10; Cel.RS On=Cellulase RS Onozuka; Mac=Macerozyme; Dri=Driselase; Pec=Pectolyase.
Protoplasts from LM were greener, larger and more vacuolated than those isolated from SE.
Protoplasts from LM treated with enzyme mixtures el and e5 had a brownish-green colour. In
the subsequent experiments the enzyme mixtures e4 and e6 were used. Results from the FDA
test showed that viability differed from one experiment to another. The highest viability of
protoplasts isolated from SE was 60 % and from LM 40 % (data not shown). Table 2
summarizes the influence of enzyme mixtures e4 and e6 on the yield and the plating efficiency
of protoplasts isolated from LM and SE of several genotypes. Protoplasts could easily be isolated
40
1.89 b 1.89 b 2.35 b 6.54 d 1.08 a 5.21 c -2.30 b 2.08 b
0.60 a 0.29 a 0.87 b 1.79 c 0.52 a 1.89 c 0.78 b 0.50 a
from all genotypes. In contrast to the pilot experiments shown in Table 1 the protoplast yield
from LM was on average higher than from SE (Table 2). This yield varied from 2.34 to 31.4
x 10 5 protoplasts/g for LM and 0.22 to 2.35 x 10 5 protoplasts/g for SE. However for the
plating efficiency, protoplasts from LM were less effective than those originating from SE.
Table 2 . Effect of genotype, tissue source and enzyme solution on protoplast yield and plating efficiency.
Enzyme mixture
e4= Cel.RS(l)/Mac(0.02) /Pec(OOOl)
e6=Cel.RS On.(l)/Mac(0.02) /Pec(O.Ol)
Genotype
Adira 4 Adira 1 Gading TMS90853 MCol. 22 MCol. 1505 Adira4 L 11 Adira 1
Protopl
LM
2.95 --
2.34 6.01 6.13 3.30 31.4 -
ast yield" (105)
SE
1.41 0.22 1.9 1.44 -
2.35 1.39 -
0.53
Plating efficiency
(%)
LM
0.48 --
0.06 0.35 0.19 0.31 0.39 -
SE
0.42 0.18 0.93 0.18 -
0.91 0.62 -
0.33
Note: Cel.RS=CellulaseRS, Cel.RS On=CellulaseRS Onozuka, lm=leaf mesophyll, Mac=Macerozym-e, Pec=Pectolyase, se=somatic embryo. ''Protoplast yield was calculated starting from 2 g of fresh leaves or somatic embryos.
The plating efficiency ranged between 0.06 to 0.48 % for protoplasts originating from LM and
between 0.18 to 0.93 % from SE (Table 2). Leaves of genotype Line 11 gave the highest
protoplast yield, followed by MCol. 1505, MCol. 22 and Adira 4. There was no association
between the yield of protoplasts and the plating efficiency. The effect of protoplast density on
plating efficiency was tested with LM protoplasts of genotype MCol. 1505. In a density of 2 X
105pp/ml and 4 X 105 pp/ml cell division occurred earlier and at a higher frequency than with
densities of 1 X 105 and 6 X 105 pp/ml (data not shown). A plating density of 2 X 105 pp/ml
was most optimal for a relatively high frequency of cell divisions. A density of 1 X 105 pp/ml
produced less cell divisions, while at a density of 6 X 105 pp/ml the development of micro-calli
was inhibited.
41
Table 3. Effect of the carbohydrate source in medium A on the occurrence of the first cell division of cultured protoplasts isolated from leaf mesophyll.
Genotype
Gading TMS90853 MCol. 22 MCol.1505
Carbohydrate source
Glucose
#Days ') #Tetrads2)
at day 11 (PE)
5 - 8 6 - 9 5 - 7 4 - 9
587 (0.29)a 365(0.18)a 486 (0.24)a 530 (0.26)a
Sucrose
#Days ')
4 - 6 5 - 7 3 - 5 4 - 6
#Tetrads2)
at day 11 (PE)
662(0.33)b 500 (0.25)a 696 (0.35)b 852 (0.43)c
Note: PE=plating efficiency, 1) = Number of days until the first cell division, 2) The mean value followed by the same letter of a row denotes no significant difference according to Duncan Multiple Range (0.05) test.
Protoplast culture
Generally, protoplasts of all genotypes underwent the first cell division after 3 - 9 days of
culture in medium A. When sucrose was used as energy source, the first two-cell divisions of
protoplasts of MCol.22 occurred 3 days after culture, whereas with glucose it occurred mostly
one day later. In cultured protoplasts of MCol. 1505, Gading and TMS90853 the first cell
divisions were observed after 5 days. The plating efficiency was in a medium with sucrose also
significantly higher than in a medium with glucose (Table 3). Almost 25% of protoplasts of
TMS90853 had changed their colour from green to brownish, their chloroplast and other
organelles aggregated and concentrated at one pole. These were clear indications for a poor
protoplast quality and low cell division competence. This phenomenon was also observed, albeit
in a lower frequency, in cultured protoplasts of the other three genotypes. Culturing of protopla
sts in medium supplemented with 2-4 mg/1 2,4-D for 2 weeks (medium A) resulted in cell
elongation (Fig. 1) and low cell division rate, whereas during a treatment of more than 24 hours
cell division was stopped completely (data not shown)
42
Micro-callus induction
After 3 weeks of culture in medium A, micro-calli were transferred to medium B for callus
development. The presence of a low concentration of 2,4-D (0.1 mg/1) combined with BAP (0.5
mg/1) resulted in the development of a white translucent callus (Table 4). A low concentration
of NAA (1-5 mg/1) combined with 0.5 mg/1 BAP produced a compact creamy-yellowish callus.
The diameter of the callus in NAA medium was larger than of callus grown in medium
containing 2,4-D. Increase of the 2,4-D or NAA concentration inhibited callus proliferation.
Without growth regulators the micro-calli did not develop well; after 10 days their growth ceased
and their colour turned from creamy white to pink.
Table 4. Influence of growth regulators on appearance and growth of microcalli from protoplasts of somatic embryos from genotype MCol. 1505 cultured on medium B. Data were taken 26 days after protoplast culture.
hormone Induction Callus Callus supplement of callus growth colour (mg/1) (%)
c w* w w c c c
Note:c=creamy colour, g=green, w=white colour, *=translucent.
After 14 days of culture in medium B, calli of ca </> 3 mm were transferred to medium C
supplemented with different growth regulators for plant regeneration. At 4 and 8 weeks after
culture in medium C growth of green callus was observed in all treatments (Table 5). A
combination of 2 mg/1 2,4-D with 1 mg/1 IAA and 0.5 mg/1 BAP gave the highest growth rate
and the highest percentage of green callus. This medium was able to maintain the callus in a
green state for more than 3 months whereas callus on the other medium combinations turned
brown. For that reason this medium was used for long term maintenance of green callus. The
43
0 2,4D(0.01) + BAP(0.5) 2,4D (1) + BAP(0.5) 2,4D (4) + BAP(0.5) NAA (0.1) + BAP(0.5) NAA (1) + BAP(0.5) NAA (5) + BAP(0.5) NAA (10) + BAP(0.5)
slow fast medium slow fast medium slow slow
5 72 45 10 64 40 24 10
hormone combinations of 0.2 mg/1 2,4-D and 0.5 mg/1 BAP followed by a medium with 1 mg/1
NAA and 10 mg/1 Zeatin ranked second best on green callus formation. The percentage varied
from 50 to 60%. The other growth regulator combinations gave lower percentages of green
callus. Development of callus pieces in the same medium varied considerably, particularly with
respect to morphology. For example, some of the compact calli were arranged in a spiral form
with 3 to 4 turns and of more than 0.7 cm height. This type of callus was usually pale yellow
or creamy in the border area and green at the top. Disk-shaped callus was developed laterally
reaching a size of 3 to 4 cm in diameter. Morphologically it was a green-compact callus, some
times irregular in form. The disk-shaped calli never produced roots. Another type of callus had
a hemispherical shape, was ca 0.5 cm high and, bright green in colour. This type consisted of
globular callus, of circa 2 mm in diameter.
In order to stimulate regeneration, green callus was cultured on medium D. Renewal of the
medium, addition of vitamins (pyridoxine, nicotinic acid and/or ascorbic acid) and reduction of
the sugar concentration did not stimulate these green calli to form shoots or embryos. After
culturing of green calli for more than 2 months nodular structures were occasionally formed,
they never developed into somatic embryos, shoots or leaf like structures but roots were initiated
occasionally instead. The highest frequency of root formation was 2%. The roots were always
initiated from the green callus part and about 20 % of the rooted calli had only one long slender
root and the rest produced 2-5 roots per callus (Fig. 2).
As elaborated earlier, protoplasts were cultured on media containing different growth regulators.
Table 6 summarizes the protocols of medium sequences, in which the protoplasts of different
genotypes were cultured. It shows that in all selected protocols green calli could be obtained;
in 8 out of 17 protocols also roots were produced. In 6 out of 11 protocols, roots were formed
from protoplasts isolated from somatic embryos of all tested genotypes. It was difficult to
indicate a causal factor of root formation. The effect of growth regulators in regeneration media
(medium D), on rooting were inconsistent. For example 0.1 mg/1 NAA in combination with 10
mg/1 BAP produced roots in protocols 2 and 6 but not in 5 and 9. The same was found with
BAP alone in medium D producing roots in protocols 4 and 13 but not in protocols 14 and 16.
44
Culturing of green callus in auxin-free media (protocol 10) resulted in root formation. However,
root formation was frequently related to the presence of NAA in the first culture medium, except
in protocol 11.
DISCUSSION
Many research groups have failed to regenerate cassava plants from protoplasts. In most cases
only callus proliferation and sometimes roots were obtained (Anonymous, 1985; Nzoghe, 1989).
Generally protoplasts are excellent for DNA uptake experiments. They have been used
successfully for plant transformation in several crops like maize (Lyznik et al. 1989),
orchadgrass ( Horn et al. 1988), rice (Kyozuka et al., 1988) and soybean (Dhir et al. 1992).
Plant regeneration from protoplasts would enable the generation of transgenic cassava plants via
protoplast transformation. In this report mature somatic embryos and leaf mesophyll cells were
used as a source of protoplasts. It was shown (Table 1) that plating efficiency of protoplasts of
somatic embryos tended to be higher, although the yield of protoplasts was lower than those
obtained from LM. A disadvantage of using LM is the difficulty in obtaining leaves which are
physiologically identical. A leaf of the first node differs from a leaf of the second node and from
nodes of the further order. This might be one of the reasons for the considerable variation in
protoplast production which was observed. Furthermore, leaf mesophyll is not a uniform source
of protoplasts. It consists of different tissues (Sinnott and Wilson, 1963). Although there were
differences in plating efficiency, protoplasts of both LM and SE developed easily into callus.
Studies with tobacco callus showed that a high ratio of auxins to cytokinins in the medium
favoured root formation and the reverse shoot formation. Although this approach is not demon
strated to be successful universally (Brown and Thorpe, 1980), this concept played an important
role in the basic understanding of the regulation of growth and development. The role of auxins
and cytokinins in plant regeneration from protoplasts has been believed to be as a determinative
factor for many crops. The embryogénie callus derived from protoplasts of pea were induced
in the presence of 0.9 mg/12,4-D, but for induction of somatic embryos hormone-free medium
45
Figure 1: Elongation of protoplasts cultured for few days in 2,4-D containing B medium.
Figure 2: Adventitious root formation on callus derived from protoplasts.
46
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was required and finally for maturation cytokinin was needed (Lehminger-Mertens and Jacobsen,
1989).
In peppermint, plant regeneration from protoplasts was induced by the presence of 1 mg/l NAA
and 0.4 mg/1 BAP followed by 0.1-0.5 mg/1 NAA and 1-5 mg/1 BAP for shoot maturation (Sato,
1993). In cassava, Shahin and Shepard (1980) used 1 mg/1 NAA combined with 0.5 mg/1 BAP
as the first (cell division induction) and second media (micro-calli induction). In the subsequent
medium NAA was reduced or replaced by IAA, while BAP was replaced by Zeatin. In this
report a wide range of auxin-cytokinin ratios has been tested. The presence of the auxin NAA
or 2,4-D in combination with cytokinin promoted callus growth (Tables 4 and 5). Callus never
developed into somatic embryos nor shoots although callus was transferred into media with
different concentrations and combinations of cytokinin. The failure of protoplasts to undergo
embryogenesis or to form adventitious shoots was either, the loss of genetic competence of
protoplasts to regenerate for example because of polyploidisation or that genes involved in
regeneration were not induced. This was possibly due to the improper supply of plant regulators,
to the physical environment stress or to the fact that the protoplasts were not competent for
regeneration (Obsorae, 1993). For the expression of regeneration the physiological state of the
plant source material, the protoplast isolation conditions, the culture medium composition and
the environment are critical factors (Constable et al., 1975 and Fowke et al., 1973). To study
every single factor determining the ability to regenerate is not easy. Many workers have found
that the plant material as a source of protoplasts is one of the most important basic factors. It
has been reported that in many plant species belonging to the Gramineae, the use of embryogénie
cell suspension cultures as the protoplast donor resulted in plant regeneration (Roest and
Gilissen, 1993). In recalcitrant woody species as for example Citrus (Base et al., 1991) regener
ation was accomplished by using protoplasts of embryogénie tissues. It was assumed that cells
of embryogénie tissue are more frequently competent for plant regeneration than those from
mature somatic embryos or leaf mesophyll.
The embryogénie competent cells in somatic embryos of cassava are regularly located two to five
cell layers deep (Raemakers et al., 1995). Histologically it was shown that the number of
50
embryogénie cells increased after 14 days of culture. It could imply that the use of young stages
of somatic embryos (immature embryos) or globular stage embryos possibly could increase the
frequency of embryogénie competent cells enabling plant regeneration. In leek ( Allium
ampeloprasum L.), Buiteveld and Creemers-Molenaar (1994) have demonstrated that
regeneration of protoplasts can be obtained if suspension cultures were used as source of
protoplasts. This suspension culture was initiated with friable embryogénie callus derived from
immature embryos (Buiteveld et al., 1994).
Recently, Taylor et al. (1995) established a new system for producing friable embryogénie callus
of cassava. These calli possibly have more competent cells than somatic embryos, which means
that relatively a high frequency of protoplasts isolated from these cells have the competence to
regenerate. The successful application of this material for protoplast regeneration will be
described in Chapter 4.
51
REFERENCES Anonymous. 1985. CIAT Annual report: Centro International de Agricultura Tropical, Cali, Columbia. P: 197-217.
Anthony P., MR. Davey, J.B. Power, C. Washington, and K.C. Lowe. 1994. Synergetic enhancement of protoplast growth by oxygenated perfluorocarbon and pluronic F-68. Plant Cell Rep. 13:251-255.
Atree, S.M., Dunstan, D.I., and Fowke, L.C. 1989. Initiation of embryogénie callus and suspension cultures, and improved embryo regeneration from protoplasts, of white spure {Picea glauca) Can.J.Bot. 67:1790-1795.
Base A., R.P. Finch and E.C. Cocking. 1991. Plant Regeneration from protoplasts of wild rice (Oryza rufipogon Griff.) Plant Cell Rep. 10:200-203.
Brown, D.C.W., and Thorpe, T.A. 1980. Adenosine phosphate and nicotinamide adenine dinucleotide pool sizes during shoot initiation in tobacco callus. Plant Physiol. 65:587-590.
Buiteveld, J., Van der Valk, P., Jansen, J., Creemers-Molenaar, J. and Colijn-Hooymans, CM. 1993. Callus induction and plant regeneration from expiants of commercial cultivars of leek (Allium ampeloprasum var. porrum L.). Plant Cell Rep. 12: 413-434.
Buiteveld, J., Fransz, P.F., and Creemers-Molenaar, J. 1994. Induction and characterization of embryogénie callus types for the initiation of suspension cultures of leek (Allium ampeloprasum L.). Plant Science. 100:195-202.
Buiteveld, J., and Creemers-Molenaar, J. 1994. Plant regeneration from protoplasts isolated from suspension cultures of leek (Allium ampeloprasum L.). Plant Science. 100:203-210.
Cock, J.H. 1985. Cassava: new potential for neglected crop. Wetview Press. Boulder and London. P:191.
Constabel, F., and Kao, K. N. 1974. Agglutination and fusion of plant protoplasts by polyethylene glycol. Can. J. Bot. 52: 1603-1606.
Dhir S.K., Dhir, S., Savka, M.A., Belanger. F., Kriz, A.L., Farrand, S.K., and Widhlom, J.M. 1992. Regeneration of transgenic soybean (Glycine max) plants from electroporated protoplasts. Plant Physiol. 99:81-88.
Dons, J. J.M., and Bouwer, R. 1986. Improving the culture of cucumber protoplasts by using an agarose-disc procedure. Proceedings of an international symposium on nuclear techniques and in vitro culture for plant improvement. Jointly organized by the International Atomic Energy Agency and the Food and Agriculture Organization of the United Nations. Held in Vienna, 19-23 August 1985. P:498-504.
Fowke L .C , Bech-Hansen, C.W., Gamborg, O. L., and Shyluk, J.P . 1973. Electron microscopic observation of cultured cells and protoplasts of Ammi visnaga. Amer. J. Bot. 60:304-312.
Horn, M.E., Shillito, R.D., Conger, B.V., and Harms, C.T. 1988. Transgenic plants of Orchadgrass
52
(Dactylis glomerata L.) from protoplasts. Plant Cell Rep. 7: 469-472.
Jenning, D.L., and Hershey, C.H. 1985. Cassava Breeding : a decade of progress from international programmes. In: Progress in Plant Breeding 1 (Eds). Rüssel, G.E. Butherworths. P: 92-103.
Kyozuka, J., Otoo, E and Shimamoto, K. 1988. Plant regeneration from protoplasts of indica rice: genotypic differences in culture responds. Theor. Appl. Genet. 76:887-890.
Lehminger-Mertens, R., and Jacobsen, H.J. 1989. Plant regeneration from pea protoplasts via somatic embryogenesis. Plant Cell Rep. 8:379-382.
Lyznik, L.A., Kamo, K.K., Grimes, H.D., Ryan, R., Chang, K.L., and Hodges, T.K. 1989. Stable transformation of maize: the impact of feeder cells on protoplast growth and transformation efficiency. Plant Cell Rep. 8:292-295.
Mathews, H., Schöpke, C , Carcamo, R., Chavarriaga, P., Fauquet, C , and Beachy, R.N., 1993. Improvement of somatic embryogenesis and plant recovery in cassava. Plant Cell Rep. 12:328-333.
Mroginski, L.A., and Kartha, K.K. 1981. Regeneration of pea (Pisum sativum L. cv. Century) plants by in vitro culture of immature leaflets. Plant Cell Rep. 1:64-66
Murashige, T., and Skoog, F. 1962. A revised medium for rapid growth and bioassay with tobacco cultures. Physiologum Plantarum. 15:473-497.
Nzoghe, D. 1989. Recherche de conditions permettant l'obtentionneoformations chez différents genotypes de manioc (Manihot esculenta Crantz). Extension a la culture de protoplastes. These. Universite De Paris Sud Centre D'Orsay. P:119.
Osborne, D. J. 1992. Morphogenic signals and markers in vitro and in vivo. In: Roubelakis-Angelakis K. A. and Kiem Tran Thanh Van (Eds). Morphogenesis in Plant Molecular Approaches. Plenum Press, New York, London. P:283.
Radke, S., and Grun, P. 1986. Isolation, culture, and regeneration of leaf mesophyll protoplasts of selected clones of Solanum. Potato Research 29:451-462.
Raemakers C.J.J.M., Schavemakers, CM., Jacobsen, E., and Visser, R.G.F. 1993. Improvement of cyclic somatic embryogenesis of cassava (Manihot esculenta Crantz). Plant Cell Rep. 12: 226-229.
Raemakers, C.J.J.M. 1993. Primary and cyclic somatic embryogenesis in cassava Manihot esculenta Crantz. PhD thesis Agricultural University Wageningen, The Netherlands. P:119.
Raemakers, C.J.J.M., Sofiari, E., Kanju, E., Jacobsen, E., and Visser, R.G.F. 1995. NAA-induced somatic embryogenesis in cassava. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:355-363.
Roest, S., and Gilissen, L.J.W. 1993. Regeneration from protoplasts. Acta Bot. Neerl. 42: 1-23.
53
Sato, H., Enomoto, S., Oka, S., Hosomi, K., and Ito, Y. 1993. Plant regeneration from protoplasts of peppermint (Mentha piperita L.) Plant Cell Rep. 12:546-550.
Schöpke, C , Muller, L.E., and Kohlenbach, H.W. 1987. Somatic embryogenesis and regeneration of plantlets in protoplast cultures from somatic embryos of coffee (Coffea canephora P ex Fr.) Plant Cell Tissue Organ Culture 8:243-248.
Shahin, E.A., and Shepard, J.F. 1980. Cassava mesophyll protoplast: isolation, proliferation and shoot formation. Plant Science Letter 17:459-465.
Shepard, J.F., Bidney, D., and Shahin, E. 1980. Potato protoplasts in crop improvement. Science 208: 17 -24.
Shimamoto, K. Terada, R., Izawa, T. and Fujimoto, H. 1989. Fertile transgenic rice plants regenerated from transformed protoplasts. Nature 338:274-276)
Sim, G.E., Loh CS . , and Goh, C.J. 1988. Direct somatic embryogenesis from protoplasts of Citrus mitis Blanco. Plant Cell Rep. 2:244-247.
Sinnott, E.W., and Wilson, K.S. 1963. Botany principles and problems. 6th. Edition. McGraw-Hill Book Company, Inc. New York, San Fransisco, Toronto, London. P:515.
Stamp, J. A. 1987. Somatic embryogenesis in cassava: the anatomy and morphology of the regeneration process. Annals of Botany 59:451-459.
Stamp, J.A. & Henshaw, G.G., 1987. Secondary somatic embryogenesis and plant regeneration in cassava. Plant Cell Tissue and Organ Culture 10:227-233.
Szabados, L., Hoyos, R., and Roca, W. 1987. In vitro somatic embryogenesis and plant regeneration of cassava. Plant Cell Rep. 6:2248-251.
Taylor, N.J., Edwards, M., and Henshaw, G.G. 1995. Production of friable embryogénie calli and suspension culture system in two genotypes of cassava. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:229-240.
Widholm, J.M. 1972. The use of fluorescein diacetate and phenosafranine for determining viability of cultured plant cells. Stain Technology. 47(4): 189-194.
Wernicke, W., and Bretteil, R. 1980. Somatic embryogenesis from Sorghum bicolor leaves. Nature. 287:138-139.
54
CHAPTER 4
PLANT REGENERATION FROM PROTOPLASTS ISOLATED FROM FRIABLE
EMBRYOGENIC CALLUS OF CASSAVA
E. Sofiari, C.J.J.M. Raemakers, J.E.M. Bergervoet, E. Jacobsen, R.G.F. Visser.
ABSTRACT
Suspensions derived from friable embryogénie callus (FEC) of cassava genotype TMS60444 were incubated in a solution consisting of enzymes (Cellulase RS Onozuka, Macerozym and Pectolyase), growth regulators (1 mg/1 2,4-D, 1 mg/1 NAA and 1 mg/1 Zeatin) and major and minor salts. Two-weeks old suspensions yielded the highest number of protoplasts (1.4 x 106
protoplasts/g fresh weight). Protoplasts plated at a density of 1-10 x 105 in a TM2G medium supplemented with 0.5 mg/1 NAA and 1 mg/1 Zeatin resulted in a plating efficiency of as high as 2.5 %. After 2 months of culture 60% of the developed calli were highly friable and in appearance identical to the original FEC. The protoplasts derived FEC were maintained in a proliferative state by culture on Gresshoff and Doy medium plus 10 mg/1 Picloram. Transfer of FEC to liquid medium resulted in suspension cultures which had a proliferation rate slightly higher than that of the original material. Culture of FEC for maturation resulted in a maximum of 124 torpedo shaped and mature embryos per 104 of initially cultured protoplasts. Mature embryos were multiplied by secondary somatic embryogenesis at high efficiency on a Murashige and Skoog medium supplemented with 8 mg/1 2,4-D. Culture of mature embryos on MS2 plus 1 mg/1 BAP resulted in shoots which were rooted easily on the same medium without BAP.
55
INTRODUCTION
Cassava (Manihot esculenta Crantz) is a perennial shrub cultivated in the lowland tropics for its
starch containing roots. Improvement of the crop by classical breeding is difficult due to low
fertility and poor seed set. Somatic hybridization of protoplasts could be an alternative to create
intra- or interspecific hybrids of sexual incompatible genotypes. For this, an efficient
regeneration system of these protoplasts is a prerequisite. Such a system could also be used to
transfer cloned genes to agronomicaly established genotypes by protoplast electroporation.
Cassava is very recalcitrant for plant regeneration of protoplasts. There is only one report of
shoot regeneration from protoplasts of cassava (Shahin and Shephard, 1980). They used well
expanded leaves for the isolation of protoplasts. Despite considerable efforts, plant regeneration
from protoplasts has never been repeated since then (Anonymous, 1985; Nzoghe, 1991; Anthony
et al., 1995, Chapter 3). A logical approach was to use tissues which contain embryogenesis
competent cells. Such cells are found in the apical meristems, young leaves and somatic embryos
cultured on auxin supplemented media (Stamp and Henshaw, 1987; Raemakers et al., 1993).
However, protoplasts isolated from these tissues gave in the best case green callus and
adventitious roots (Chapter 3).
Recently, a new type of somatic embryogenesis was developed. In this in vitro system the
embryos do not develop beyond the pre-globular stage and the embryogénie callus is highly
friable (Taylor et al., 1995). Transfer of this friable embryogénie callus to liquid medium
resulted in a suspension-like culture. In leek (Buitenveld and Creemers, 1994), petunia (Power
et al., 1979), rice (Kyozuka et al., 1988), sugarcane (Chen, et al., 1988), and wheat (Chang et
al., 1991) such cultures were an excellent source for protoplast regeneration. Furthermore,
electroporation of protoplasts derived from suspension cultures led to the transformation of maize
(Rhodes et al., 1988), rice (Toriyama et al., 1988) and orchardgrass (Horn et al., 1988).
In this report the use of friable embryogénie callus as source for protoplasts has been described.
Starting with these protoplasts two routes of plant regeneration have been described. One leading
to friable embryogénie callus and the other directly to mature embryos. The mature embryos
56
could be converted into plants.
MATERIALS AND METHODS
Plant material
Friable embryogénie callus (FEC) of cassava genotype TMS60444 was kindly provided by Dr.
Nigel Taylor of University of Bath, United Kingdom. Every three weeks FEC was subcultured
on Gresshoff and Doy (1972) medium supplemented with vitamins and minerals, 20 g/1 sucrose
and 10 mg/1 Picloram (GD2). Suspension cultures were initiated by transferring 0.5 g of FEC
into a 300 ml flask with 50 ml of liquid medium supplemented with Schenk and Hildebrandt
(1972) salts and vitamins, 60 g/1 sucrose and 10 mg/1 Picloram (SH6).
The medium was refreshed every 2 days and after 14 days the content of a each flask was
subdivided over 5 new flasks. Cultures were agitated on a L.E.D. Orbit Shaker (Lab-Line
Instruments, Inc.) at 130 - 150 rpm. All cultures were kept in a growth chamber with a
photoperiod of 12 hours, a temperature of 30 °C and an irradiance of 40 jtmol'V.
Isolation of protoplasts
In a preliminary experiment the yield of FEC cultured on GD2 and of suspensions cultured for
1 to 4 weeks in liquid SH6 medium was determined. For protoplast isolation this tissue was
sieved (mesh 1 mm2) and 2 grams of the sieved tissue was placed in a Petri-dish (<j) 9cm)
containing 10 ml of a mixture of enzymes (10 g/1 Cellulase RS Onozuka, 200 mg/1 Macerozym,
10 mg/1 Pectolyase), growth regulators (1 mg/1 NAA, 1 mg/1 2,4-D, 1 mg/1 Zeatin), major and
minor salts (368 mg/1 CaCl2, 34 mg/1 KH2P04, 740 mg/KN03, 492 mg/1 MgS04.7H20, 19.2
mg/1 Na-EDTA, 14 mg/1 FeS04.7H20).
Cells were incubated for about 16 hours on a L.E.D. Orbit Shaker (Lab-Line Instruments, Inc.)
at 30 rpm in darkness. Further steps of the protoplast isolation procedure were as described in
Chapter 3.
57
Assessment of protoplast viability and the presence of cell walls
The viability of freshly isolated protoplasts was observed using FDA (Widholm, 1972). FDA
(0.5 mg/ml in acetone) was mixed with washing solution (Chapter 3) in a ratio of 1:50. An equal
volume of the FDA solution was added to protoplasts. After five minutes the protoplasts were
examined with a fluorescence Axiophot Photomicroscope using an aniline blue filter. Calcofluor
White was used to check the remnant of cell walls. An equal volume of 0.4 M mannitol solution
containing 0.1 % w/v calcofluor white (Hughes and Gunning, 1975) were mixed with
protoplasts. After 10 minutes the protoplast suspensions were examined with a fluorescence
Axiophot Photomicroscope using a blue filter.
Protoplast culture
Protoplasts were cultured and plated in media solidified with Sea Plaque agarose 0.2 % w/v as
described in Chapter 3. In three experiments the influence of different parameters was studied.
In the first experiment, protoplasts were cultured at a density of 105 protoplasts/ml (pp/ml) on
TM2G medium (Wolters et al., 1991) supplemented with different growth regulators. In
experiment two, protoplasts were cultured at densities of 2x10s, 5x10s or lxlO6 pp/ml on TM2G
supplemented with 0.5 mg/1 NAA and 1 mg/1 Zeatin. In experiment three, protoplasts were
cultured at densities of lxlO5 or lxlO6 pp/ml on TM2G medium or medium A (Murashige and
Skoog (1962) salts and vitamins, 4.5 g/1 myo-inositol, 4.55 g/1 mannitol, 3.8 g/1 xylitol, 4.55
g/1 sorbitol, 0.098 g/1 MES, 40 mg/1 adeninsulphate and 150 mg/1 caseinhydrolysate, 0.5 mg/1
d-calcium-panthotenate, 0.1 mg/1 choline-chloride, 0.5 mg/ ascorbic acid, 2.5 mg/1 nicotinic
acid, 1 mg/1 pyridoxine-HCl, 10 mg/1 thiamine-HCl, 0.5 mg/1 folic acid, 0.05 mg/1 biotine, 0.5
mg/1 glycine, 0.1 mg/1 L-cysteine and 0.25 mg/1 riboflavine and 59.40 g/1 glucose, 0.5 mg/1
NAA and 1 mg/1 Zeatin). The media were refreshed every 10 days, by replacing 9 ml with fresh
medium. The plating efficiency was calculated after 20 days.
After two months of culture of protoplasts and (micro)calli in the first medium, high quality
FEC was selected and either cultured for further proliferation or for maturation. For
proliferation FEC was transferred to Gresshoff and Doy (1974) medium supplemented with 40
g/1 sucrose, 7 g/1 Daichin agar and 2 mg/1 Picloram (GD4). After 3 weeks the FEC was
58
transferred to a Gresshoff and Doy medium supplemented with 20 g/1 sucrose, 7 g/1 agar and
10 mg/l Picloram (GD2). Suspension cultures were initiated by transferring 1.0 g of FEC to
liquid SH6% medium supplemented with 10 mg/1 Picloram. Two weeks later the suspension was
divided over new flasks with an initial packed cell volume of 1.0 ml. The increase in packed cell
volume was observed for two weeks and compared with the original material.
For maturation FEC was cultured on a medium consisting of Murashige and Skoog (1962) salts
and vitamins, 0.1 g/1 myo-inositol, 20 g/1 sucrose, 18.2 g/1 mannitol, 0.48 g/1 MES, 0.1 g/1
caseinhydrolysate, 0.08 g/1 adenine sulphate, 0.5 mg/1 d-calcium-panthotenate, 0.1 mg/1 choline
chloride, 0.5 mg/1 ascorbic acid, 2. mg/1 nicotinic acid, 1 mg/1 pyridoxine-HCl, 10 mg/1
thiamine HCl, 0.5 mg/1 folic acid, 0.05 mg/1 biotin, 0.5 mg/1 glycine, 0.1 mg/1 L-cysteine, 0.25
mg/1 riboflavine and 1 mg/1 Picloram. This maturation medium was refreshed every 3 weeks.
The torpedo shaped embryos were isolated and cultured on medium supplemented with
Murashige and Skoog (1962) salts and vitamins, 20 g/1 sucrose, 7 g/1 agar (MS2) and 0.1 mg/1
BAP.
Subculture of mature embryos
Mature embryos were either cultured directly on MS2 plus 1 mg/1 BAP for shoot development,
or on solid or in liquid MS2 supplemented with 10 mg/1 NAA or 8 mg/1 2,4-D for secondary
embryogenesis.
RESULTS
Protoplast isolation and culture
The suspension cultures consisted predominantly of small clusters of dense cytoplasmic cells
which have a light-brown colour under a light microscope. The protoplasts isolated from
suspension cultures were heterogeneous both in their size and in the amount of cytoplasm. The
age of the suspension culture was a critical factor.
The protoplast yield of friable embryogénie callus harvested directly from solid GD2 medium
59
was much lower than of the suspension cultures. Two weeks old suspensions gave the highest
and 4 weeks old suspension cultures the lowest yield of protoplasts (Table 1).
Table 1. The effect of suspension culture duration on protoplast yield, viability and with the calcofluor white test on cell wall remnants (mean from 3 replicates).
Duration
(weeks)
0 1 2 3 4
Protoplast yield
(105/gr)
0.5 7 14.5 8.16 1.18
Viability determined by FDA
(% positive cells)
32+2 30±8 33±5 28+2 26±1
Presence of cell walls determined by calcofluor white ( % positive cells)
nd 4.75 3.77 3.5 nd
nd=not determined
Fig. 1A shows a sample of protoplasts isolated from suspensions. With FDA viable protoplasts
showed a yellow-green fluorescence. These protoplasts were spherical and displayed cytoplasmic
streaming. Independent of the suspension culture duration around 30% of the total amount of
isolated protoplasts was viable (Table 1). Results from the calcofluor white staining showed that
about 4 % of the protoplasts fluoresced brightly, indicating the presence of cell walls. However,
most of these protoplasts did not have a spherical shape and showed no reaction with FDA.
Plating efficiency and micro-callus development
In the first experiment protoplasts were cultured in TM2G medium supplemented with different
growth regulators (Table 2). Protoplasts, cultured in 0.5 mg/1 NAA and 1 mg/1 Zeatin, or in
0.5-4 mg/1 Picloram and 1 mg/1 Zeatin divided after three to four days. In a medium without
growth regulators or in a medium with only Zeatin this was observed after 8-12 days, and in
medium with 10 mg/1 Picloram plus 0.5 mg/1 Zeatin there was almost no division of protoplasts.
60
Table 2. The effect of growth regulators on plating efficiency of protoplasts after culture for 30 days in medium TM2G and on the formation of torpedo shaped and mature embryos after 60 days on maturation medium.
Growth regulators
(mg/1)
No hormone Zea (1) NAA(0.5) + Zea(l) Pic(0.5) + Zea(l) Pic(2) + Zea(l) Pic(4) + Zea(l) Pic(10) + Zea(l)
PE
(%)
0.02 0.06 0.67 0.45 0.49 0.08 < 0.01
Days to first
cell division
12 8-9 3-4 3 3 3 nd
# torpedo shaped and mature mature embryos per 104 protoplasts
nd 4.75a 184.2c 6.75a 47.40b 3.4a nd
Data were taken as an average from 3 to 4 replications (one drop of 100 jtl protoplasts solution), mean followed by the same letter denote no significant difference according to LSD (0.05) test; nd=not determined; PE=plating efficiency.
The plating efficiency varied from 0.02 % in a medium without growth regulators to 0.67% in
TM2G medium supplemented with 0.5 mg/1 NAA and 1 mg/1 Zeatin. The media supplemented
with 0.5-4 mg/1 Picloram gave intermediate plating efficiencies. Plating efficiency was also
influenced by the density of the cultured protoplasts. In Table 3 it can be seen that a density of
5 x 105 gave the highest (0.23 %) and a density of 106 the lowest plating efficiency (0.02 %).
Table 3. The effect of protoplast density on plating efficiency (after 21 days of culture) in TM2G supplemented with 0.5 mg/1 NAA and 1 mg/1 Zeatin and on the formation of torpedo shaped and mature embryos (after 2 months in the first medium followed by 2 months in maturation medium).
Densities Plating efficiency # torpedo shaped and mature (105) (%) at 21 days embryos per 104 protoplasts
2 3 5 10
Data were taken as an average from 3-4 replications (one drop of 100 /tl of protoplast suspension).
61
0.10+0.04 0.15+0.03 0.23+0.04 0.02+0.01
124 85 30 5
Plating efficiency varied considerably between experiments. In general, however, the same trend
was observed. In Table 4 it can be seen that 106 gave a lower plating efficiency than 105.
Furthermore, it can be seen that TM2G medium is superior over medium A. After 20 days of
culture in TM2G medium supplemented with 0.5 mg/1 NAA and 1 mg/1 Zeatin the first micro-
calli, consisting of at least 2 types (Fig. IB), became visible. In the first type, cell division
occurred inside the boundaries of the initial cell wall, so the daughter cells became smaller than
the original protoplasts whereas the shape of the micro-calli was irregular. In the second type,
most probably cell division occurred in a different way because the cells could not be observed
as easily as in the first type. Some of the cells had a banana-like shape and were transparent.
Table 4. The effect of basal medium and protoplast density on plating efficiency (after 21 days of culture) and production of micro-calli (after 2 months of culture).
105 pp/ml 106 pp/ml
Medium PE Micro-calli PE Micro-calli (growth regulators) (%) per 104 pp (%) per 10" pp
TM2G (0.5 mg/1 NAA + 1 mg/1 Zeatin) 2.5 1058+158 0.91 64+17.25 A (0.5 mg/1 NAA + 1 mg/1 Zeatin) 0.24 240+85 0.18 25+9
Data were taken as an average from 5 to 10 agarose drops at 55 days of culture (one drop is equal to a 100 /xl protoplasts suspension), PE=plating efficiency.
After 2 months of culture, 104 protoplasts cultured in TM2G supplemented with 0.5 mg/1 NAA
and 1 mg/1 Zeatin at a density of lOVml produced 1058 micro-calli, whereas 104 protoplasts
cultured at a density of 106/ml only produced 64 micro-calli. Replacing TM2G medium with
medium A reduced at both densities the number of micro-calli significantly (Table 4). At this
stage at least three types of calli could be distinguished. One type consisted of globular shaped
embryos (Fig. 1C) which were mostly observed in protoplasts cultured at a density of 106. Some
of them developed cotyledon like structures, light green in colour. However, these embryos
could not be germinated properly. Another type was fast growing and consisted of a large
compact callus, they were observed in protoplast cultures of both densities. This callus never
62
developed embryos. The third type was highly friable callus and was observed at both densities
(Fig. 1C). At a density of 2-5 x 105 (medium TM2G) about 60 % of the calli were friable and
embryogénie. The FEC was either subcultured for further proliferation or for maturation.
Proliferation of FEC
Following selection of FEC, 0.1 g of it cultured for three weeks on GD 4 plus 2 mg/1 Picloram
increased into 0.7 g of tissue. More than 95 % of the tissue consisted of high quality FEC.
Subsequently, this tissue was maintained by subcultures of three weeks on GD2 medium
supplemented with 10 mg/1 Picloram. To initiate suspension cultures FEC was transferred to
liquid medium. A suspensions cultured for 6 weeks in liquid SH6 medium is shown in Fig. ID.
The increase in packed cell volume (PCV) of this material was slightly higher than that of the
original material (data not shown).
Maturation of FEC
In an attempt to induce maturation of embryos, FEC isolated after two months of culture in
TM2G was cultured on maturation medium. On this medium there is a gradual shift from
proliferation to maturation. As a result the packed cell volume had increased with a factor 4 after
two weeks of culture in liquid maturation medium. Also after transfer to solid maturation
medium there is proliferation. After two weeks on solid medium most of the embryos had
reached a globular shape (Fig. IE) and only a few of these globular embryos developed further.
The first torpedo shaped embryos became visible after one month of culture on solid maturation
medium (Fig. IF). The number of mature and torpedo shaped embryos was not correlated with
the plating efficiency but with the density of the initially cultured protoplasts (Table 3). No such
embryos were obtained if protoplasts were cultured on TM2G without growth regulators (Table
2). The highest number of mature and torpedo shaped embryos was formed from protoplasts
cultured on TM2G supplemented with 0.5 mg/1 NAA and 1 mg/1 Zeatin. If NAA was replaced
by Picloram than the number of torpedo shaped and mature embryos was significantly lower
(Table 2). From the tested Picloram concentrations 2 mg/1 gave the best results. After 3 months
of culture between 60 and 200 torpedo shaped and mature embryos were isolated per agarose
drop. Torpedo shaped embryos became mature at high frequency if they were cultured on fresh
63
maturation medium or on MS2 plus 0.1 mg/1 BAP.
Secondary somatic embryogenesis and shoot development
Table 5. Response of mature embryos on the induction of secondary embryogenesis on several media.
Treatment # expiants # embryos which form secondary embryos
solid MS2 + 8 mg/1 2,4-D 30 28 (93) liquid MS2 + 8 mg/1 2,4-.D 30 25 (83) solid MS2 + 10 mg/1 NAA 30 10 (33) liquid MS2 + 10 mg/1 NAA 30 14 (45) 7 days solid 2,4-D/ 20 days liquid NAA 30 24 (80)
Between brackets percentage
Only a few torpedo shaped embryos formed secondary embryos if cultured on liquid or solid
MS2 medium supplemented with 10 mg/1 NAA or 8 mg/1 2,4-D (data not shown). Mature
embryos were better expiants for secondary embryogenesis. In both liquid and solid medium 2,4-
D was superior for induction of secondary embryogenesis as compared to NAA. If mature
embryos were first cultured in 2,4-D and than in liquid NAA the response was comparable with
culture in 2,4-D alone. Also embryos which first had undergone a cycle of secondary somatic
embryogenesis in medium with 2,4-D, produced highly efficient secondary embryos in NAA
supplemented medium. About 30% of the mature embryos cultured on MS2 plus 1.0 mg/1 BAP
developed into shoots. These shoots were easily rooted on MS2 (Fig. IG).
64
Fig. 1: Regeneration of plants from protoplasts: isolated protoplasts A), development of two types of micro-callus after 20 days of culture B), development of friable embryogénie callus (f) and globular shaped embryos (g) after 2 months of culture C), suspensions made of friable embryogénie callus D), formation of globular embryos from friable embryogénie callus E), formation of torpedo shaped (t) and mature embryos (m) and rooted plantlet G).
65
DISCUSSION
Nowadays in rice, leek (Buiteveld and Creemers-Molenaar, 1993) and maize regeneration from
protoplasts is no longer a barrier for the genetic improvement of these crops (Abdullah et al.,
1986, Kyozuka et al., 1987 and Rhodes et al., 1988). With one exception (Shahin and Shepard,
1980) in cassava regeneration of plants from protoplasts has been tried, without success, using
many types of explants as source for protoplasts (Anonymous, 1985; Nzoghe, 1989; Chapter 3).
The plant regeneration from protoplasts described here brings new possibilities for the
improvement of this crop. The most important aspect of this procedure is the use of friable
embryogénie callus or suspensions derived from it. Important for high frequency regeneration
of protoplasts is the use of suspensions instead of FEC as source of protoplasts (Table 2), and
is the culture of protoplasts on TM2G medium supplemented with NAA and Zeatin (Table 3,
5) in a density of 1x10s protoplasts/ml (Table 3 and 4).
De Jong et al., (1993) showed that the percentage of suspension cells of carrot suspension
cultures that regenerated into plants was not more than 2%. In the best case 2.5 % of the
cassava protoplasts underwent cell division and formed micro-calli (Table 4). Although not all
microcalli produced embryos. Anthony et al., (1995) improved plating efficiency by culturing
protoplasts of cassava with short glass rods in ammonium-free MS medium. Buiteveld and
Creemers-Molenaar (1994) improved plating efficiency by plating protoplasts of leek isolated
from suspension cultures in Ca-alginate medium. These procedures might also increase plating
efficiency of cassava protoplasts derived from FEC.
Two months after isolation of protoplasts two different routes of regeneration could be chosen:
maturation of embryos or further proliferation of the FEC. This is exactly the same as the
response obtained with the original material. In some treatments the number of torpedo shaped
and mature embryos exceeded the number expected from the plating efficiency. However,
maturation occurred at a low frequency; less than 10% of the individual friable embryos
developed into mature embryos. The fact that in some treatments the number of obtained
organized embryos exceeded the plating efficiency can be explained by the fact that during the
66
first two months of culture micro-calli are in reality proliferating FEC and by the fact that there
is a gradual shift from proliferation to maturation. Another bottle neck was the germination of
mature embryos into plants. This problem could be solved by first multiplying single mature
embryos through secondary embryogenesis. In this way the chance that plants were derived from
individual mature embryos was maximized. However, the whole procedure always will be a time
consuming process and it is expected to be genotype dependent as was shown by Raemakers
(1993) for secondary somatic embryogenesis.
With the availability of a system by which protoplasts can regenerate into plants a new road is
open to genetic transformation of cassava. Electroporation or PEG mediated DNA transfer or
cocultivation with Agrobacterium might be ways to obtain transformed friable callus. Initial
transformation experiments by electroporation of protoplasts derived from secondary embryos
has shown that this way is certainly an attractive possibility (data not shown). Furthermore, the
protoplast regeneration system described here is repeatable and is an important first step,
towards the application of interspecific protoplast fusion in cassava.
67
REFERENCES
Anonymous, 1985. CIAT: Annual report: Centra International de Agricultura Tropical, Cali, Columbia. P: 197-217.
Abdullah, R., Cocking, E.C. and Thompson, J.A., 1986. Efficient plant regeneration from rice protoplasts through somatic embryogenesis. Bio/Technology 4:1087-1090.
Anthony, P., Davey, M.R., Power, J.B., and Lowe, K.C. 1995. An improved protocol for the culture of cassava leaf protoplasts. Plant Cell Tissue and Organ Culture. 42:229-302
Buiteveld, J., and Creemers-Molenaar, J. 1994. Plant regeneration from protoplasts isolated from suspension cultures of leek (Allium ampeloprasum L.). Plant Science. 100:203-210.
Chang, Y.F., Wang, W.C., Colleen, Y.W., Nguyen, H.T., and Wong, J.R. 1991. Plant regeneration from protoplasts isolated from long-term cell cultures of wheat (Triticum aestivum). Plant Cell Rep. 9:611-614.
Chen, W.H., Davey, M.R., Power, J.B., and Cocking, E.C. 1988. Sugarcane protoplasts: factors affecting division and plant regeneration. Plant Cell Rep. 7:344-347.
Gresshoff, P.M., and Doy, C.H. 1974. Development and differentiation of haploid Lycopersicon esculentum (tomato). Planta 107:161-170.
Horn, M.E., Shillito, R.D., Conger, B.V., and Harms, C.T. 1988. Transgenic plants of orchardgrass (Dactylis glomerata L.) from protoplasts. Plant Cell Rep. 7:469-472.
Hughes, J., and McCully, M.E. 1975. The use of an optical brightener in the study of plant structure. Stain Technology. 50:319.
Kyozuka, J., Otoo, E., and Shimamoto, K. 1988. Plant regeneration from protoplasts of indica rice: genotypic differences in culture respond. Theor. Appl. Genet. 76:887-890.
Mathews, H., Carcamo, R., Chavarriaga, P., Schöpke, C.P., Fauquet, C. and Beachy, R.N., 1993. Improvement of somatic embryogenesis and plant recovery in cassava. Plant Cell Rep. 12:328-333.
Mukherjee, A. 1995. Embryogenesis and regeneration from cassava calli of anther and leaf. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P.375-377.
Murashige, T., and Skoog, F. 1962. A revised medium for rapid growth and bioassay with tobacco cultures. Physiol. Plantarum. 15:473-497.
Nzoghe, D. 1989. Recherche de conditions permettant l'obtentionneoformations chez différents genotypes de manioc (Manihot esculenta Crantz). Extension a la culture de protoplastes. These. Universite De Paris Sud Centre D'Orsay. P :119.
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Power, J.B., Bery, S.F., Chapman J.V., and Cocking, E.C. 1979. Somatic hybrids between unilateral cross-incompatible Petunia species. Theor. Appl. Genet. 55:97-99.
Raemakers, C.J.J.M., Amati, M., Staritsky, G., Jacobsen, E., and Visser, R.G.F. 1993. Cyclic somatic embryogenesis and plant regeneration in cassava. Annals of Bot. 71:289-294.
Rhodes, C.A., Pierce, D.A., Metler, I.J., Mascarenhas, D., and Detmer, J.J. 1988. Genetically transformed maize plants from protoplasts. Science 240:204-207.
Shahin, E.A., and Shepard, J.F. 1980. Cassava mesophyll protoplasts: isolation, proliferation and shoot formation. Plant Science Letter 17:459-465.
Schenk, R.U., and Hildebrandt, A.C. 1972. Medium and techniques for induction and growth of monocotyledonous and dicotyledonous plant cell cultures. Can. J.Bot. 50:199-204.
Stamp, J.A. and Henshaw, G.G., 1987. Secondary somatic embryogenesis and plant regeneration in cassava. Plant Cell Tissue and Organ Culture 10:227-233.
Taylor, N.J., Edwards, M., and Henshaw, G.G. 1995. Production of friable embryogénie calli and suspension culture system in two genotypes of cassava. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:229-240.
Toriyama, K., Arimoto, Y., Uchimiya, H., and Hinata, K. 1988. Transgenic rice plants after direct gene transfer into protoplasts. Bio/Technology. 6:1072-1074.
Wolters, A.M.A., Schoenmakers, H.C.H., van der Meulen-Muiser, J.J.M., van der Knaap, E., Derks, F.H.M., Koornneef, M., and Zelcer, A. 1991. Limited DNA elimination from the irradiated potato parent in fusion products of albino Lycopersicon esculentum and Solanum tuberosum. Theor. Appl. Genet. 83:225-232.
Widholm, J.M. 1972. The use of fluorescein diacetate and phenosafranine for determining viability of cultured plant cells. Stain Technology. 47(4): 189-194.
69
CHAPTER 5
PRODUCTION OF TRANSGENIC CASSAVA PLANTS
BY PARTICLE BOMBARDMENT USING LUCIFERASE ACTIVITY AS SELEC
TION MARKER.
C.J.J.M. Raemakers, E. Sofiari, N. Taylor, E. Jacobsen and R.G.F. Visser.
ABSTRACT Cassava embryos derived from friable embryogénie callus of the genotype TMS60444 were bombarded with DNA of the constructs pJITlOO or PJIT64. Both constructs contain the firefly luciferase (LUC) gene driven by the 35S promoter. The influence of several particle gun machine parameters and pretreatment of plant material on transient LUC activity were studied. Two weeks after bombardment pieces of friable calli with one spot showing LUC activity were selected. In total 67 independent LUC spots, derived from 5 experiments, were further cultured either in liquid or on solid medium. One spot was cultured per plate or flask. In the subsequent selection rounds all spots of one individual plate or flask were cultured as one individual group. In this way different transformation events were separated and multiplied. Eight weeks after bombardment 34 cultures still contained LUC activity and the mean number of LUC spots per culture had increased from 1 to 4.6 in liquid medium and to 2.5 in solid medium. After two more months of subsequent culture and LUC selection the transformed nature of these cultures was confirmed on the molecular level using the polymerase chain reaction assay. Friable embryos derived from one transformation event were cultured for maturation. In total 24 of the 467 tested mature embryos were LUC positive. After multiplication of the LUC positive mature embryos by cyclic somatic embryogenesis they were allowed to grow into shoots and to root on basic medium. The analyzed plantlets contained multiple copies of the inserted DNA. The presented method enables us to transform this particular cassava genotype, thus allowing the genetic improvement of the important tropical crop cassava by transgenesis.
70
INTRODUCTION
Cassava (Manihot esculenta Crantz) is a short lived shrub of 1-5 m in height which is cultivated
for its starch containing tuberous roots (Byrne, 1984; Cock, 1985). Since 1990 a number of
laboratories have attempted to establish a transformation procedure for this crop (Schöpke et al.
1993; Arias-Garzon and Sayre, 1993; Raemakers, 1993; Luong et al., 1995; Sarria et al., 1995).
All these groups have utilized somatic embryogenesis as method of regeneration. It is initiated
from zygotic embryos (Stamp and Henshaw, 1982) or from leaves (Stamp and Henshaw, 1987a;
Szabados et al., 1987; Taylor et al., 1993; Mathews et al., 1993; Raemakers et al., 1993a). The
primary embryos produced in this fashion can then be induced to enter continuous cycles of
secondary somatic embryogenesis by repeated subculture of embryos on auxin supplemented
medium. The embryos generated by this culture system are highly organized and develop readily
into mature embryos (Raemakers et al., 1993b,c; Mathews et al., 1993). There is only one
report of successful use of this secondary system of embryogenesis for cassava transformation.
This was done using a wild type Agrobacterium tumefaciens strain (Sarria et al., 1995).
However, because the plants contain the wild type Ti-plasmid of the Agrobacterium strain,
including the oncogenes, they are probably of no agronomical value. Furthermore, the duration
of the experiments and the efficiency in which only a few -presumed- transgenics were obtained
makes this procedure not feasible. Attempts to use strains without oncogenes were all
unsuccessful. Secondary somatic embryogenesis in conjunction with particle bombardment
(Schöpke et al. 1993, Arias-Garzon and Sayre, 1993) or electroporation (Luong et al., 1995) has
led to chimeric transformed embryos. However, subculture of these embryos for repeated cycles
of secondary somatic embryogenesis did never result into stably, fully, transformed plants.
In cassava a low percentage of the embryogénie tissue has a friable nature. This friable tissue
can be isolated, purified and multiplied, resulting in almost complete friable embryogénie
cultures. In this system with friable embryogénie callus the embryos are less organized. The
embryos do not develop beyond the pre-globular stage, but instead proliferate new embryos from
the surface of the units (Taylor et al., 1995). In cassava, this is the first report which describes
the use of this friable embryogénie system in combination with particle bombardment.
71
Furthermore, it is the second report where in a crop recalcitrant for transformation, the
luciferase reporter gene (isolated from Photinuspyralis), was used for selection of transformants.
Previously this selection system was used successfully to obtain transformed plants in
Dendrobium (Chia et al., 1994). The luciferase enzyme requires luciferin, ATP, Mg2+, and 02
to produce light (560 ran). Plant cells expressing luciferase and supplied with luciferin emit
photons (Ow et al., 1986) which can be detected with a luminometer. It is shown that this
specific, friable, form of somatic embryogenesis, combined with the detection of transformed
tissue using luciferase activity, leads to cultures with transgenic friable embryos which after
culture for maturation and germination develop into luciferase positive plants. It was shown by
Southern hybridization that the selected plants contain the introduced DNA stably integrated in
their genome.
MATERIAL AND METHODS
Plant material
The initiation of friable embryogénie callus cultures was as described before (Taylor et al.,
1995). Highly friable embryoids of genotype TMS60444 were maintained on a medium
consisting of Gresshoff and Doy (1972) vitamins and salts, 7 g/1 Daichin agar, 20 g/1 sucrose
and 10 mg/1 Picloram (solid GD2). Every three weeks the friable embryos were subcultured on
the above mentioned medium. In order to initiate liquid suspension cultures 0.5 g of friable
embryos was transferred in a flask of 200 ml with 50 ml of liquid medium supplemented with
Schenk and Hildebrandt (1972) salts and vitamins, 60 g/1 sucrose and 10 mg/1 Picloram (liquid
SH6). The medium was refreshed every 2 days and after 14 days the content of each flask was
divided over 5 new flasks. The pH was adjusted to 5.7 before autoclaving. The temperature in
the growth chamber was 30°C, the photoperiod 12 hours and the irradiance 40 /xmoltnV.
Constructs and coating of DNA on the particles.
In one experiment, DNA from the plasmid PJIT64 and in all other experiments DNA from
pJITlOO (kindly provided by J.F. Guerineau, John Innes Institute, UK) were used. The plasmid
72
PJIT64 contains the firefly luciferase under control of two 35S promoters and the CaMV
polyadenylation region and the plasmid pJITlOO contains the firefly luciferase and the
phosphinothricin acetyl transferase gene both under control of the 35S promoter and the CaMV
polyadenylation region (Guerineau and Mullineaux, 1993). Plasmid DNA was isolated using
Wizard™ Maxipreps DNA purification system of Promega.
A method adjusted from McCabe et al. (1988) was used to coat DNA on the particles. Eighty
lig of DNA was mixed with 10 mg of gold particles (1.6 /mi, BioRad), 30 /d 5 M NaCl, 5 /tl
2 M tris HCl pH 8.0, 115 /iL H20, 100 /tl 25% PEG 1550, 100 /tL 0.1 M spermidine and 50
/tl 2.5 M CaCl2. After centrifugation the pellet was resuspended in 10 ml of absolute alcohol and
briefly sonificated. One hundred sixty /xl of the gold suspension was pipetted through the
appature of an inverted macrocarrier holder onto a standard macrocarrier (Bio Rad). After 5
minutes the macrocarrier holder was removed. The macrocarrier covered with a thin layer of
gold beads was dried in an oven (10 minutes, 40 °C) and used for bombardment.
Bombardment of suspensions culture
Suspension culture derived friable embryos, cultured in liquid SH6 medium for a period of as
short as 5 min to as long as 7 weeks, were sieved (mesh 1 mm2) and collected on filters (81
/xm). Per bombardment 0.05 g of friable embryos (approximately 2500 units) was spread in the
centre of a plate with solid (7 g/1 Daichin agar) SH6 medium. Plates were bombarded using the
PDS-1000He biolistic device (BioRad). The distance between the rupture disc and the macro-
carrier was 0.5 cm and between the macrocarrier and the stopper plate 0.5 cm. The effect of
different helium pressures (450-1800 p.s.i.) combined with different vacuum levels (15 or 26
inches Hg vacuum) and distances of the plate to the stopper plate (5 or 8 cm) were tested on the
transient luciferase (LUC) activity one day after bombardment. After bombardment the friable
embryos were cultured for one day on solid SH6 after which they were either transferred to
liquid SH6 or solid (first 3 days on Gresshoff and Doy (1972) medium supplemented with 7 g/1
Daichin agar, 40 g/1 sucrose and 10 mg/l Picloram (GD4) than on a Greshoff and Doy medium
with 20 g/1 sucrose, instead of 40 g/1).
73
In another experiment the effect of different pretreatments on transient LUC activity was tested.
For this solid GD2 cultured friable embryogénie callus was sieved and cultured in liquid SH2,
SH4 or SH6 medium for three days. The cultures were bombarded at 450 p.s.i and the friable
embryos were divided over solid SH2, SH4 and SH6.
Selection and multiplication of luciferase (LUC) positive friable embryos
The first selection of LUC positive expiants was done two weeks after bombardment. In the
experiments used for optimization of transient activity this was the second and in the other
experiments the first LUC assay. The friable embryos in a 1 cm radius around a LUC positive
spot were cut out of the agar and subcultured in liquid (SH6) or solid (first 3 days GD4 than
GD2) medium. One spot was cultured per flask or plate. In the next selection rounds (every 2
weeks) the positive spots of individual cultures were isolated and cultured together.
Maturation and germination of friable embryos
Cultures containing at least 1 % LUC positive friable embryos were grown for maturation on a
medium consisting of Murashige and Skoog (1962) salts and vitamins, 0.1 g/1 myo-inositol, 20
g/1 sucrose, 40 g/1 mannitol, 0.48 g/1 MES, 0.1 g/1 caseinhydrolysate, 0.08 g/1 adenine sulphate,
0.5 mg/1 d-calcium-pantothenate, 0.1 mg/1 choline chloride, 0.5 mg/1 ascorbic acid, 2. mg/1
nicotinic acid, 1 mg/1 pyridoxine-HCl, 10 mg/1 thiamine HCl, 0.5 mg/1 folic acid, 0.05 mg/1
biotin, 0.5 mg/1 glycine, 0.1 mg/1 L-cysteine, 0.25 mg/1 riboflavine. The pH was adjusted to
5.7 before autoclaving. Every two weeks the LUC positive expiants were transferred to fresh
medium until they became mature. LUC positive mature embryos were multiplied by cyclic
somatic embryogenesis in liquid medium supplemented with Murashige and Skoog (1962) salts
and vitamins, 20 g/1 sucrose (MS2) and 10 mg/1 NAA as described previously (Raemakers et
al., 1995a). Multiplied mature embryos were cultured for shoot development on medium
supplemented with Murashige and Skoog (1962) salts and vitamins, 20 g/1 sucrose, 8 g/1 Daichin
agar (MS2) and 1 mg/1 BAP. Shoots were rooted on MS2.
Luciferase (LUC) assays
Tissues cultured in liquid medium were collected on filters (82 jtm) and spread on solid GD4
74
medium. The explants were sprayed with 0.25 mg/ml luciferin (Promega, E160) and assayed
for luciferase (LUC) activity with a VIM intensified CD camera and Argus-50 photon counting
image processor from Hamamatsu Phototonic Systems. Cultures of 1 day, 2 and 4 weeks after
bombardment were measured for 1 minute. In the later assays this was less than 30 seconds.
Molecular analysis.
Genomic DNA was isolated for PCR from approximately 50 mg friable embryos and for
Southern hybridization from 300 mg green leaf tissue of in vitro plantlets using a method
described by Salehuzzeman et al. (1993). Primers LUC1 (ACG GTT TTG GAA TGT TTA CTA
C) and LUC2 (CGG TTG TTA CTT GAC TGG CGA C) were synthesized (Eurogentec) and
yielded a 792 bp fragment corresponding to an internal portion of the luciferase gene. A 50 ^1
PCR reaction mix contained the primers (50 pM), Taq polymerase (0.2 U), dNTP (80 /*M of
each), 1XPCR reaction buffer and 50 ng of the isolated DNA. The reaction mix was overlaid
with 50 ßh mineral oil. PCR conditions were 92°C initial melting, for 10 min, 30 cycles of
92°C/2 min and 47 °C/2 min and a 72°C/2 min final extension. Southern hybridization was
performed as described (Salehuzzeman et al., 1993) using 8 pg of EcoRV or Bglll restricted
DNA of cassava and the luciferase gene as a probe.
RESULTS
Optimization of transient activity.
Nine different experiments were conducted in order to optimize bombardment treatments for
transformation. The tested variables are presented in Table 1. In the first 5 experiments the
influence of some variables concerning the particle gun and pretreatment on the transient LUC
activity were studied. These transient studies were not performed in the last four experiments.
Machine variables
In the first experiment (Table 1) friable embryos were placed 5 cm below the stopperplate and
75
bombarded with different helium pressures at 26 inch Hg vacuum. A helium pressure of 450
p.s.i. was found to result in the highest transient luciferase (LUC) activity with more than
30.000 photons being detected in one minute. A Petri dish bombarded with pJITlOO and sprayed
with water, instead of luciferin, produced 56 photons/min and a Petri dish bombarded with a
control construct without the LUC gene and sprayed with luciferine produced 87 photons/min.
An example of transient LUC activity of a culture bombarded with 450 p.s.i. is shown in Fig.
1A. The scale in this figure represents different numbers of emitted photons. At this
magnification it is difficult to count individual spots, but at a higher magnification at least 300
distinct spots/cm2 could be identified. The luciferase activity decreased rapidly. Fifteen minutes
after application of luciferin the LUC activity had decreased by 29% and after 2 hours only 8%
of the original activity could be detected. As the BioRad gun cannot operate at helium pressures
lower than 450 p.s.i. the distance to the stopper plate, combined with the partial vacuum
pressure was varied to reduce the momentum of the particles (Table 1: experiment 2). The
transient activity of cultures bombarded under the same conditions as in experiment 1 was
10.623 photons/min which is a factor three lower than in this first experiment. The same level
of transient activity was observed after the vacuum level was decreased to 15 inc. Hg or after
the distance of the material to the stopperplate was increased to 8 cm. However, if both the
lower vacuum level and the greater distance were combined, than the luciferase activity
decreased to 300 photons/min. In the above described two sets of experiments the cultures were
bombarded once. Two shots per plate resulted in a LUC activity which was almost twice as high
as compared to one shot per plate (Table 1: experiment 3).
76
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Plant material
In experiment 4 (Table 1) the effect of different pre- and post-transformation culture media
on transient LUC activity was studied. Pre-culture of friable embryos in SH2 medium gave
the lowest and in liquid SH6 medium the highest transient LUC activity, independently of
the post-treatment. There was an interaction between the post-culture media and the pre-
culture media on transient LUC activity. Post-culture in SH6 medium gave the highest
transient LUC activity in friable embryos pre-cultured in SH6 and SH4. However, post-
culture in SH4 gave the highest transient activity in friable embryos pre-cultured in SH2. In
experiments 1 to 4 the friable embryos were cultured for a period varying from 2 days to 6
weeks in liquid SH6 before they were bombarded. Between the experiments there was not
a clear relation between the pre-culture duration in SH6 and the transient LUC activity (Table
1), probably this might be caused by experimental variations. In order to assess the effect of
the time in liquid culture, friable embryos were transferred to liquid medium for 5 min, 2
days or 7 weeks before they were bombarded (Table 1: experiment 5a). Friable embryos
cultured for 5 minutes in liquid SH6 produced only 9.107 photons and this increased to
36.515 photons/min after they were cultured for 2 hours in liquid SH6. The highest activity
was found with friable embryos which had been subcultured for 7 weeks.
Detection of LUC positive friable embryos 14 days after bombardment
Fourteen days after bombardment the LUC activity was seen to be decreased to less than 2%
of the level observed after 1 day (data not shown) and it was possible to distinguish distinct
LUC spots (Fig. IB). In the different experiments, the number of LUC spots per bombarded
plate (LUC/bp) is given in the last column of Table 1.
The highest number of LUC spots per bombarded plate was observed in the experiments 5b,
6, 7, 8 and 9 where the first LUC assay was performed 14 days after bombardment. In the
experiments 1 to 5a where also transient activity was measured, a maximum of 1.6 LUC
spots/bp was recorded (Table 1: experiment 5a). In the two experiments where different
helium pressures were compared there was either no effect of the pressure on the number of
LUC spots per bombarded plate (Table 1: experiment 1) or a slight increase (Table 1:
experiment 8) with using higher pressures. In experiments 1 and 8, respectively, 1.0 and 0.5
LUC spots/bp were detected. No spots were detected if the acceleration of particles was
78
further reduced by either a lower level of vacuum or a longer distance of the plant material
to the stopper plate (Table 1: experiment 2). In experiment 5a (Table 1), where different
preculture durations were tested, a preculture of 5 minutes did not result in LUC spots
whereas 7 weeks gave clearly more spots than 2 hours.
Subculture and multiplication of LUC positive friable embryos
The friable embryos around a LUC spot were cut out of the agar and subcultured in either
liquid SH6 or on solid GD2 medium. To separate the different transformation events one
LUC spot was cultured per flask or plate.
Table 2: The efficiency of luciferase selection for the recovery of cultures with transformed friable embryos.
Exp
1 5 7
8 9
§ of cultures with LUC spots
Treatment
liquid solid solid liquid solid liquid Total
Weeks after bombardment 2
6 33 4 3 18 3 67
4
4 20 4 3 12 1 44
6
3 16 4 3 10 1 37
8
3 15 4 2 9 1 34
In the next selection rounds each flask or plate was treated as one individual culture and all
the spots of one culture were subcultured as belonging to one group. A total of 67 LUC spots
was subcultured: 12 in liquid and 55 on solid medium. Two weeks later 44 cultures still
contained LUC spots: 8 in liquid and 36 on solid medium. This was not correlated with the
strength of the spot isolated two weeks after bombardment. In some cases very bright spots
had disappeared whereas low intensity spots became very bright after 4 weeks. In the next
selection round the decrease in LUC positive cultures was lower. Four more disappeared
during subculture from week 6 to 8 because of infection. Eight weeks after bombardment 34
cultures were still LUC positive. The mean number of LUC spots was in liquid cultures 4.6
and in solid cultures 2.5. From 8 weeks on in all 34 cultures the number of LUC positive
79
explants per culture doubled every 2-4 days. The highest efficiency of the transformation
procedure, calculated as the number of cultures which still contain LUC spots 8 weeks after
bombardment per bombarded dish was 2.0 in experiment 7. In this experiment 7 spots were
detected 2 weeks after bombardment (Table 1) of which one spot was lost during culture
(Table 2).
Maturation of LUC positive friable embryos and development into shoots
Because there was no experience with maturation of friable embryos, one culture, containing
transformed friable embryos (Table 1 : experiment 9; friable embryos were transformed with
pJIT64) was, taken to optimize this process. For this the fraction of transformed friable
embryos was increased by continuous LUC selection.
80
Figure 1: Luciferase activity of suspension derived callus bombarded with pJIT64: A) 1 day after bombardment (x 4), B) 2 weeks after bombardment (x 1.2), C) 4 months after bombardment (x 1.2), D) mature embryo derived from friable embryogénie callus (x 15), E) mature embryo multiplied by secondary somatic embryogenesis (x 1.2), F) plants developed from secondary embryo cultures (x 1.2). 8 1
Friable embryos as shown in Fig. IC were used for maturation. After 4 weeks of culture on
maturation medium the first mature embryos were isolated and assayed for LUC activity. In
total 467 mature embryos derived from one transformation event were assayed of which 24
were LUC positive (Fig. ID). LUC positive mature embryos were multiplied by culturing
in liquid MS2 medium supplemented with 10 mg/1 NAA or in solid MS2 medium
supplemented with 8 mg/1 2,4-D. In the first medium 5 out of 12 and in the second medium
10 out of 12 of the mature embryos formed secondary embryos (Fig. IE). Of the initial 22
LUC positive mature embryos 12 initiated LUC positive secondary cultures and two were
LUC negative. In total about 300 mature embryos were cultured for shoot development on
MS2 medium supplemented with 1 mg/1 BA. The first shoots appeared one month after
culture and in total 21 shoots were obtained. Al these shoots were LUC positive (Fig. IF).
Molecular analysis
From 8 cultures friable embryos with LUC activity were analyzed by PCR. All cultures gave
a band of the expected size for both the luciferase gene and the phosphinofhricin acetyl
transferase gene (data not shown), indicating the stable integration of the construct in these
cultures. DNA from two secondary cultures of mature embryos and of two regenerated plants
derived from experiment 9 (Table 1) were restricted with EcoRV or Bglll. The banding
patterns of the four different samples are identical (Fig. 2). Because EcoRV, and Bglll cuts
the luciferase gene once it can be concluded that a minimum of four copies are stably
integrated in the plant genome.
« ««-« « a « « • b
« ««• c • mm d
f 9
Figure 2: Southern blot hybridization of DNA isolated from secondary embryogénie culture (a and b), regenerated trnsformed plant (c and d) and control non-transformed plant (f and g).DNA was restricted with Bgll (a,c,f), and EcoRV (b,d,g). Lane e is a marker lane.
82
DISCUSSION
Previously, cassava embryos induced by secondary or cyclic somatic embryogenesis were used as
target tissue for transformation (Schöpke et al. 1993, Arias-Garzon and Sayre, 1993, Luong et al.,
1995, Sarria et al., 1995, Chapter 2). In only one case, by using Agrobacterium tumefaciens, this
resulted in transformed plants (Sarria et al., 1995). However, the plants contained the wild-type Ti
plasmid and the procedure was not repeatable. This paper is the first report were cassava has been
transformed reproducibly with only genes of interest. This was accomplished by combining a new
system of somatic embryogenesis (Taylor et al., 1995) with a selection system based on the activity
of the firefly luciferase gene (Ow et al., 1986). This friable embryogénie callus or suspension culture
system differs in several aspects from cyclic somatic embryogenesis. In the friable system embryos
do not develop beyond the pre-globular stage whereas in cyclic embryogenesis the embryos develop
readily into mature embryos. In both types of somatic embryogenesis there is a phase were new
embryos are initiated, followed by a phase of growth and development of the initiated embryo. The
time period between two moments of initiation and growth or development is much shorter in friable
than in cyclic somatic embryogenesis. As a consequence the cells in friable embryos are more often
in a state of initiation whereas in cyclic somatic embryogenesis they are for a longer period in a state
of growth and development. An initiation state is advantageous for plant transformation because a cell
has than the chance to act independently from neighbouring cells and form a new embryogénie unit.
Another difference is the fact that in friable embryogenesis the embryos originate from epidermal
cells, possibly single cells (Taylor et al., 1995). In cyclic somatic embryogenesis the embryos
originated from a group of cells and this group consisted of epidermal and mesophyllic cells (Stamp,
1987; Raemakers et al., 1995b).
LUC based selection has many advantages over selection with ß-glucuronidase (GUS). The most
important one is the non-destructive nature of the LUC assay; positive expiants can be selected and
subcultured. The GUS assay is destructive. The GUS protein is very stable; it has in mesophyll cells
a half life time of more than 50 hours (Jefferson et al., 1987). The LUC protein has a half life time
of about 3 hours in mammalian cells (Thompson et al., 1991). Although data on the half life time in
plant cells are not available, the fact that two hours after supply of luciferin the LUC activity is
reduced to 8% suggests that the enzyme is not long lived. A consequence of a longer half life time
is that the transiently produced enzyme will be active for a longer time period thus overestimating the
transformation efficiency. A short enzymatic half life time has as advantage that there is no build up
of enzyme and that gene/enzyme activity can be tested repetitively (Luehrsen et al., 1992).
83
Furthermore, plant tissue does not contain endogenous LUC activity which might interfere with the
assay as is observed for the GUS enzyme.
LUC based selection has also advantages above chemical selection (reviewed by Wilmink and Dons,
1993) by antibiotics as kanamycin or herbicides as phosphinothricin. On one extreme the chemical
selection might be to rigorous leading to the loss of the regenerative capacity of the transformed
tissue. This was observed in transformation of friable embryogénie callus of barley (Stiff et al.,
1995), Norway spruce (Robertson et al., 1992), white spruce (Bommineni et al., 1993) and banana
(Sâgi et al., 1995) where no plants could be regenerated from chemically selected transformed callus.
In such cases LUC based selection would ensure regeneration. On the other extreme chemical
selection might not be strong enough resulting in a high percentage of recovered plants which are not
transgenic. If this were the case LUC selection combined with chemical selection would reduce labour
because only positive expiants are subcultured and the ones without LUC activity are discarded. The
LUC gene is also an option in plants where chemical selection does not work as was reported for
Dendrobium (Chia et al., 1994).
In spite of the fact that pJITlOO contains the phosphinothricin acetyl transferase gene, ppt was not
used for the selection of transgenic events. Since ppt, even at a concentration as high as 10 mg/1, was
not able to completely inhibit the growth of non-transformed tissue, it was not used in the experiments
described here. It is however, obvious that the presence of this marker gene in the transformed tissue
(FEC, maturing FEC, mature embryos and plants) will be used to investigate the use of ppt resistance
as a selection system in transformation of cassava.
From the here presented data it seems that for the optimal result it is important to use friable embryos
which have been subcultured for at least one week in liquid SH6 medium. The friable embryos should
be bombarded with particles which have a momentum equal or higher than that is obtained with 450
p.s.i., vacuum of 26 inc Hg and a distance of the plant material to the stopperplate of 5 cm. The
efficiency of this procedure was as high as 2 (Table 1,2 experiment 7) successful transformation
events per bombarded dish. At this moment all cultures which were used in maturation experiments
yielded LUC positive mature embryos (results not shown). The obtained efficiencies are in agreement
with other crops where embryogénie suspension cultures were used as target tissue for bombardment.
For example in maize the number of transformation events yielding transformed plants varied between
0.6 and 1 per bombarded dish (Fromm et al., 1990, Gordon-Kamm et al., 1990). In peanut 2
transformation events leading to transformed plants were observed per bombardment (Ozias-Akins
84
étal., 1993).
After bombardment this transformation system counts 4 phases. First friable embryos originating from
one transformation event are allowed to proliferate. If enough transformed friable embryos are
available than a part can be stored in liquid nitrogen and the other part is used for maturation (second
phase). In the third phase mature embryos are multiplied by cyclic somatic embryogenesis before they
are allowed to grow into plants (fourth phase). This 4 phases system will guarantee that the percentage
of transformation events leading to transformed plants is maximized. If there is a future demand than
friable embryos of a specific transformation event can be taken out of the liquid nitrogen and can be
used for further molecular analysis or for the introduction of additional genes of interest. It is obvious
that we have a method for cassava transformation available which needs to be extended to other
genotypes and genes. However, the fact that a repeatable transformation system is within reach opens
up the possibilities to improve this important crop cassava by genetic modification.
ACKNOWLEDGEMENT This work was partly financed by the Directorate General for International Cooperation of the
Ministry of Foreign Affairs of the Netherlands (SBO-DGIS), AVEBE 6a, The Netherlands and
National Starch and Chemical Co. USA. We furthermore would like to acknowledge the help of the
Cassava Biotechnology Network which in the way of a small grant made it possible to collaborate
with the University of Bath and Rothampstad Experimental Station in the UK.
85
REFERENCES
Arias-Garzon, D.I., Sayre, R.T. 1993. Tissue specific inhibition of transient gene expression in cassava (Manihot esculenta Crantz). Plant Science 93:121-130.
Bommineni, V.R., Chibbar, R.N., Datla, R.S.S. andTsang, E.W.T. 1993. Transformation of white spruce (Picea glauca) somatic embryos by particle bombardment. Plant Cell Rep. 13:17-23.
Byrne, D. 1984. Breeding Cassava. In: Janick, J. (Eds). Plant Breeding reviews, vol 2, AVI Westport CT, USA, P:73-113.
Chia, T.F., Chan, Y.S., and Chua, N.H., 1994. The firefly luciferase gene as a non-invasive reporter for Dendrobium transformation. The Plant Journal 6:441-446.
Cock, J.H. 1985. Cassava: New Potential for a neglected crop. Wetview Press, Boulder and London. P:191.
Fromm, M.E., Morrish, F., Armstrong, C , Williams, R., Thomas, J., and Klein T. 1990. Inheritance and expression of chimeric genes in the progeny of transgenic maize. Bio/Technology 8:833-839.
Gordon-Kamm, W.J., Spencer, T.M., Mangano, M.L., Adams, T.A., Daines, R.J., Start, W.G., O'Brien, J.V., Chambers, S.A., Adams, W.R., Willets, N.G., Rice, T.B., Mackey, C.J., Krueger, R.W., Kausch, A.P. and Lemaux, P.G. 1990. Transformation of maize cells and regeneration of fertile transgenic plants. The Plant Cell 2:603-618.
Gresshoff, P.M. and Doy H.M. 1972. Development and differentiation of haploid Lycopersicon esculentum (tomato). Planta 170:161-170.
Guerineau, F. and Mullineaux, P.M. 1993. Plant transformation and expression vectors. In: Croy, R.R.D. (Eds), Plant molecular biology, Labfax, BIOS Scientific publishers, Oxford, UK. P: 121-148.
Jefferson, R.A., Kavanagh, T. and Bevan, M.W., 1987. GUS fusion: ß-glucuronidase as a sensitive and versatile gene fusion marker in higher plants. The EMBO Journal 6:3901-3907.
Luehrsen, K.R., De Wet, J.R. and Walbot, V. 1992. Transient expression analysis in plants using firefly luciferase reporter gene. Methods in Enzymology 216:397-414.
Luong, H.T., Shewry, P.R., and Lazzeri, P.A. 1995. transient gene expression in cassava somatic embryos by tissue electroporation. Plant Science 107: 105-115.
Mathews, H., Schöpke, C , Carcamo, R., Chavarriaga, P., Fauquet, C. and Beachy, R.N., 1993. Improvement of somatic embryogenesis and plant regeneration in cassava. Plant Cell Rep 12:328-333.
McCabe, D.E., Swain, W.F., Martinelli, B.J. and Christou, P. 1988. Stable transformation of soybean (Glycine max) by particle acceleration. Bio/Technology 6:923-926.
Murashige, T. and Skoog, F., 1962. A revised medium for rapid growth and bioassay with tobacco cultures. Physiologum Plantarum 15:473-494
Ow, D.W., Wood, K.V., DeLuca, M., De Wet, J.R., Helinsky, D.R. and Howell, S.H. 1986.
86
Transient and stable expression of the firefly luciferase gene in plant cells and transgenic plants. Science 234:856-859.
Ozias-Akins, P., Schnall, J., Anderson, W.F., Sinsit, C , demente, T.E., Adang, M.J. and Weissinger, A.K. 1993. Regeneration of transgenic peanut plants from stably transformed embryogénie callus. Plant Science 93:185-194.
Raemakers, C.J.J.M. 1993. Primary and cyclic somatic embryogenesis in cassava Manihot esculenta Crantz. PhD thesis Agricultural University Wageningen, The Netherlands. P:119.
Raemakers, C.J.J.M., Bessembinder, J., Staritsky, G., Jacobsen, E. and Visser, R.G.F., 1993a. Induction, germination and shoot development of somatic embryos in cassava. Plant Cell, Tissue and Organ Culture 33:151-156.
Raemakers C.J.J.M., Amati, M., Staristsky, G., Jacobsen, E. and Visser, R.G.F. 1993b. Cyclic somatic embryogenesis in cassava. Annals of Botany 71:289-294.
Raemakers C.J.J.M., Schavemakers, CM., Jacobsen, E. and Visser, R.G.F. 1993c. Improvement of cyclic embryogenesis of cassava (Manihot esculenta Crantz). Plant Cell Rep 12:226-229
Raemakers C.J.J.M., Sofiari, E., Kanju, E., Jacobsen E. and Visser, R.G.F., 1995a. NAA induced somatic embryogenesis in cassava. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P: 355-364.
Raemakers, C.J.J.M., Jacobsen E. and Visser, R.G.F., 1995b. Histology of somatic embryogenesis and evaluation of somaclonal variation. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P: 336-354.
Robertson, D., Weissinger, A.K., Ackley, R., Glover, S. and Sederof, R.R. 1992. Genetic transformation of Norway spruce {Picea abies (L) Karst) using somatic embryo expiants by microprojectile bombardment. Plant Molecular Biology 19:925-935.
Sâgi, L., Panis, B., Remy, S., Schoofs, H., De Smett, K., Swenne, R. and Cammue, B.P.A. 1995. Genetic transformation of banana and plantain (Musa spp.) via particle bombardment. Bio/Technology 13:481-485.
Salehuzzeman, S.N.I.M., Jacobsen, E., and Visser, R.G.F. 1993. Isolation and characterization of a cDNA encoding granule-bound starch synthase in cassava {Manihot esculenta Crantz) and its antisense expression in potato. Plant Mol. Biol. 23:947-962.
Sarria, R., Torres, E., Balcazar, N., Destefano-Beltran, L and Roca, W.M. 1995. Agrobacterium mediated transformation of cassava. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia, 22-26 August 1994. P: 241-244.
Schenk, R.U. and Hildebrandt, A.C., 1972. Medium and techniques for induction and growth of monocotyledonous and dicotyledonous plant cell cultures. Can. J. Bot. 50:199-204.
Schöpke, C , Franche, C , Bogusz, D., Chavarriaga, P., Fauquet, C , Beachy, R.N. 1993. Transformation in cassava. In: Biotechnology in agriculture and forestry, vol. 23. Bajaj, Y.P.S. (Eds). Springer-Verlag, Berlin, Heidelberg. P: 273-289.
87
Stamp, J.A. and Henshaw, G.G. 1982. Somatic embryogenesis in cassava. Zeitschrift fur Pflanzenphysiologie 105:183-187.
Stamp, J. A. 1987. Somatic embryogenesis in cassava: the anatomy and morphology of the regeneration process. Annals of Botany 59:451-459.
Stamp, J. A. and Henshaw, G.G. 1987a. Somatic embryogenesis from clonal leaf tissue of cassava. Annals of Botany 59:445-450.
Stamp, J.A. and Henshaw, G.G. 1987b. Secondary somatic embryogenesis and plant regeneration in cassava. Plant Cell, Tissue and Organ Culture 10:227-233.
Stiff, CM. , Kilian, A., Zhou, H., Kudrna, D.A. and Kleinhofs, A. 1995. Stable transformation of barley callus using bio-listic particle bombardment and the phosphinothricin acetyltransferase (bar) gene. Plant Cell, Tissue and Organ Culture 40:243-248.
Szabados, L., Hoyos, R. and Roca, W. 1987. In vitro somatic embryogenesis and plant regeneration of cassava. Plant Cell Rep 6:248-25
Taylor, N.J., Clarke, M., and Henshaw, G.G. 1993. The induction of somatic embryogenesis in fifteen African cassava cultivars. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings First Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P:134-137.
Taylor, N.J., Edwards, M., and Henshaw, G.G. 1995. Production of friable embryogénie calli and suspension culture system in two genotypes of cassava. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia 22-26 August 1994. P:229-240.
Thompson, J.F., Hayes, L.S. and Lloyd D.B. 1991. Modulation of firefly luciferase stability and impact on studies of gene regulation. Gene 103:171-178.
Wilmink, A., and Dons, H.J.M. 1993. Selective agents and marker genes for use in transformation of monocotyledonous plants. Plant Mol. Biol. Reporter 11:165-185.
88
CHAPTER 6
COMPARISON OF GERMINATION OF NAA AND 2,4-D INDUCED SOMATIC EMBRYOS OF CASSAVA (MANIHOT ESCULENTA CRANTZ).
E. Sofiari, K. Danso, C.J.J.M. Raemakers, E. Jacobsen, R.G.F. Visser
ABSTRACT
In cassava the germination of cyclic somatic embryos, induced in liquid medium by the auxins 2,4-dichlorophenoxyacetic acid (2,4-D) or naphthalene acetic acid (NAA), was compared for four different genotypes. In all genotypes desiccation stimulated normal germination of NAA induced embryos. However, the desiccated embryos, required a medium supplemented with cytokinins such as benzylaminopurine (BAP) for high frequency germination. The morphology of the resulting seedling was dependent on the concentration of BAP. With 1 mg/1 BAP plants with thick and short taproots and branched shoots with short internodes were formed. With 0.1 mg/1 BAP the taproots were thin and slender and the shoot had only one or two apical meristems. If the embryos were desiccated sub-optimally, higher concentrations of BAP were needed than if the embryos were optimally desiccated to stimulate germination. Also desiccated embryos which were cultured in the dark required a lower concentration of BAP and, furthermore, these embryos germinated faster than embryos cultured in the light. Complete plants were obtained four weeks after the start of somatic embryo induction. 2,4-D induced embryos showed a different response. In only one genotype desiccation enhanced germination of 2,4-D induced embryos and in three other genotypes it did not. In all genotypes desiccation stimulated root formation. Embryos cultured in the dark formed predominantly adventitious roots, whereas embryos cultured in the light formed predominantly taproots.
89
INTRODUCTION
Cassava (Manihot esculenta Crantz) is a perennial crop of the family Euphorbiaceae, grown
mainly for its enlarged tuberous roots. The crop has many advantages: it is drought tolerant,
can be grown in diverse edapho-climatic conditions, in depleted soils and is able to recover
from damage caused by severe incidence of pests, diseases and bushfires (Cock, 1985).
These advantages and the adaptability to indigenous farming systems explain the rapid
spread of the crop on the African and Asian continents (Byrne, 1984). Cassava has a
potential yield of 90 tonnes per hectare per year (Cock, 1985). However, the average yield
in Indonesia is 10.3 tonnes per hectare (Soenarjo et al., 1987), and in Africa it is even lower
(Anonymous, 1993). This low yield has been attributed to the poor fertility of the soils where
cassava is grown, deterioration of roots and severe incidence of pests and diseases. The
African Cassava Mosaic Virus, for example, can cause yield losses of up to 95% (Bocks and
Woods, 1983). Beside the lack of resistant genotypes, the use of stakes infected with diseases
and pests enhanced their persistence. There is lack of good healthy planting materials. Such
planting material can be produced via meristem culture. In 1975 this technique was used to
free cassava from Cassava Mosaic Virus (Kartha and Gamborg 1975). Healthy plants can be
produced in large numbers by multiple shoot culture (Smith et al., 1986). However, this
technique requires several tissue culture steps (mechanical isolation of cuttings, rooting of
cuttings and hardening of plants) which makes the procedure labour intensive. In principle,
labour could be reduced if planting materials are produced via somatic embryogenesis.
Somatic embryos have the developmental program to grow into complete plants without
mechanical isolation and separate shooting and rooting steps (Parrot et al., 1991). In cassava
somatic embryogenesis was first reported by Stamp and Henshaw (1982) and since then by
several groups as an efficient regeneration system (Szabados et al., 1987; Mathews et al.,
1993; Raemakers et al., 1993abc). Embryos are induced on leaves or zygotic embryos cultu
red on auxin supplemented medium. The primary embryos recultured on auxin supplemented
medium produce secondary embryos and continuous subculture of embryos allows the
development of cyclic embryogénie cultures (Stamp and Henshaw 1987; Mathews et al.,
1993; Raemakers et al., 1993bc). The auxin 2,4-D initiates both primary and cyclic embryo
genesis, NAA in contrast, only cyclic embryogenesis (Chapter 2). To use somatic
embryogenesis for plant multiplication the embryos should germinate efficiently into seedling-
90
like cassava plants. To achieve this goal, Raemakers et al., (1993b,c) cultured mature 2,4-D
induced embryos on a medium supplemented with 1 mg/1 BAP. Depending on the genotype
between 10% (MCol.1505) and 70% (MCol.22 and TMS90853) of the embryos developed
into plants (Raemakers, 1993). The process of germination was slow, the plants were initially
malformed and lacked taproots. Adventitious roots were formed after culture of plants on
growth regulator-free medium. A germination process whereby genotype-independent com
plete normal plants with taproots are produced within a short period of time is desirable.
Mathews et al., (1993) improved germination by desiccating embryos. With this method 85 %
of MCol. 1505 embryos, induced on 2,4-D supplemented solid medium, germinated into com
plete plants compared to 5% for undesiccated embryos.
High frequency germination of mature embryos is also of importance for the application of
the protoplast and genetic modification technology for cassava improvement. It was shown
that only a low percentage of the mature embryos derived from protoplasts (Chapter 4) and
from transformed mature embryos (Chapter 5) developed into plants.
In this report germination of embryos induced in liquid medium is described. It is shown that
NAA induced embryos differ from those induced by 2,4-D. Furthermore, it is shown that
besides desiccation the use of cytokinins and darkness during culture for germination are
important factors in obtaining complete plants in a number of different cassava genotypes.
MATERIALS AND METHODS
Plant material and growth conditions
The cassava (Manihot esculenta Crantz) genotypes TMS 90853, Line 11, Adira 4 and Gading
were used in this study. Primary embryos were produced following the method described by
Raemakers et al., (1993a). In brief: young leaf lobes (1-6 mm) were cultured on solid (8 g/1
Daichin agar) basal medium (BM) supplemented with 20 g/1 sucrose (BM) plus 8 mg/12,4-D
(step one). BM consisted of Murashige and Skoog (1962) salts and vitamins. After 20 days
expiants were transferred to BM supplemented with 0.1 mg/1 BAP for maturation (step two).
Mature embryos are defined as structures with a distinct hypocotyl and green cotyledons.
Mature embryos were isolated from the leaf expiants, chopped into fine pieces and cultured
in 300 ml flasks with 75 ml liquid BM supplemented with 8 mg/12,4-D or 10 mg/1 NAA for
91
the production of cyclic embryos. Cultures were placed on a gyrator (LAB-Line Instruments
Inc., model 3519) at 120 rpm. After 15 (NAA) and 30 (2,4-D) days of culture mature
embryos were chopped again and cultured in the same media for a new cycle of embryo-
genesis. In this way the embryos used in this study were maintained for 2 years (TMS
90853), 1 year (Adira 4) and xh year (Gading and Line 11). All cultures were kept in a
growth chamber with a photoperiod of 12 hours, a temperature of 30 °C and an irradiance
of 40 /rniol'V1.
Methods to achieve desiccation and subsequent germination of embryos.
Mature NAA induced embryos of Adira 4 were subjected to various desiccation treatments
for a period of 7 days. After the desiccation the embryos were cultured for germination on
solid BM supplemented with 1.0 mg/1 BAP.
Petri-dish desiccation
Mature embryos (12 g of fresh weight) induced in liquid medium were transferred to sterile
Whatmann 3 mm filter paper to absorb hanging water. After 1 hour the weight of the
embryos had decreased to 35 percent. Four grammes of the dried embryos were transferred
to empty Petri plates, weighed, sealed with parafilm and stored in the growth chamber. The
Petri-dishes were changed every other day to remove condensed water. The percentage of
desiccation was calculated from the ratio between the weight of the dried embryos after and
before Petri-dish desiccation, multiplied by 100.
Desiccation using glycerol
After removal of hanging water, 4 gr of dried mature embryos were transferred to an empty
Petri-dish and placed in a desiccator (2 1) containing 200 ml of a 87% glycerol solution to
control the internal humidity.
Desiccation by using sugar solutions
Four grammes of mature embryos were transferred to solid BM supplemented with 0-160
g/1 sucrose, or liquid BM supplemented with 0-60 g/1 sucrose, or H20 supplemented with 0-
60 g/1 sucrose, or liquid BM supplemented with mannitol (0-10 g/1).
92
The effect of different growth regulators on embryo germination.
To study the effect of growth regulators on embryo germination, NAA induced Petri-dish
desiccated embryos of Adira 4 were cultured on BM, BM supplemented with TDZ (0.1, 1,
4 mg/1), BAP (0.5, 1, 4 mg/l), Kinetin (0.5, 1, 4 mg/1), IBA (1, 5, 10 mg/1) or NAA (1,
5, 10 mg/1).
Effect of degree of moisture loss on embryo germination.
To study the relation between moisture loss and germination, Petri-dishes with mature NAA
induced embryos were either placed in 500 ml jars filled with 50 ml of 0, 0.05, 0.2 mg/1
NaCl (Gading) or were placed in 2 1 jars filled with 50 ml of a 0, 60, 87% glycerol solution
(Adira 4). After 7 days the embryos were cultured for germination on BM supplemented with
0-4 mg/1 BAP.
Influence of light/dark regime on germination of desiccated embryos.
Mature NAA or 2,4-D induced embryos of TMS 90853, Line 11, Adira 4 and Gading were
desiccated using the Petri-dish method and cultured on BM supplemented with 0-4 mg/1 BAP,
either in the dark or in the light.
Histology
Taproots of embryos were fixed in aqueous FAA solution (4 % formalin, 5 % acetic acid and
50 % ethanol), dehydrated through an ethanol series of 70, 80, 90 and 100 %. Hereafter, the
expiants were embedded in Technovit 7100. Sections of 4-6 /*m were made with a Reichert-
Jung 2050 Supercut microtome and stained with 1 % toluidine blue in an aqueous solution
of 1 % Na-tetraborate.
Evaluation
Embryos cultured in the dark/light experiment were evaluated after 14 and 28 days of culture
and in all other experiments after 28 days. The embryos were evaluated individually for
presence or absence of roots, the morphology of the roots (thin or thick, taproots or
adventitious) and presence or absence of shoots. A shoot was present when an internode had
appeared with at least one primary leaf. An embryo was considered to be germinated if it had
both a root and a shoot.
93
RESULTS
The effect of different desiccation methods on embryo germination.
Different desiccation methods were used to stimulate germination from mature somatic
embryos of the cassava genotype Adira 4 (data not shown). Non-desiccated embryos did not
germinate into complete plants with roots and shoots. Only a small number of the cultured
embryos formed either roots or shoots (17 and 3% respectively). In the Petri-dish and
glycerol desiccation methods the moisture loss could be determined. In the Petri-dish method
the dried embryos lost a further 40% of their fresh weight and in the glycerol method 55 per
cent. In both methods 88% of the embryos germinated into complete plants with taproots and
shoots. The remaining embryos formed only shoots or roots. To obtain an effective
desiccation it was essential that the liquid cultured embryos were first dried on filter paper
to remove hanging water. If this was not done only a few embryos germinated. Because
water condensed on the lids of the Petri-dishes it was further essential that every other day
the embryos were transferred to a new Petri-dish to remove the water.
In the desiccation methods using sugar solutions the moisture loss could not be determined
exactly. At lower concentrations of sugars the embryos continued to grow, indicated by an
increase of fresh weight. When higher concentrations of sugars were used the growth ceased.
In all treatments less than 10 % of the embryos germinated. Although the glycerol
desiccation was comparably as good as the Petri-dish desiccation the latter was chosen
because of its simplicity for further experimentation.
The influence of growth regulators on embryo germination.
The embryos used in this experiment lost 20% of their fresh weight. The dried embryos were
cultured on different media (Table 1). None of the embryos cultured on growth regulator-free
medium germinated or formed shoots and only 1 embryo formed roots (Table 1). The auxins
IBA and NAA stimulated only root formation. For this NAA was more effective than IBA.
With 4.0 mg/1 NAA 66% of the embryos formed roots (Table 1). The roots formed were
abundant, thin and, in contrast to IBA where tap roots were formed, adventitious of origin.
All the tested cytokinins stimulated germination and/or shoot formation. TDZ gave the lowest
94
percentage of germination; at all the concentrations tested not more than 12 percent
germinated. Germination increased with higher concentrations of kinetin. On a medium
supplemented with 4 mg/1 kinetin 36% of the embryos germinated and 18% formed only
shoots (Table 1). The roots of these embryos were normal thin tap roots (Fig. 1A) and the
shoots had more than one apical meristem. The highest percentage of shoot development
(with and without roots) was observed when embryos were cultured on BAP supplemented
medium. The optimal BAP concentration was found to be 1.0 mg/1. At this concentration
about 67% of the embryos developed shoots and 14% germinated. The morphology of the
roots and shoots of embryos was dependent on the BAP concentration. Embryos cultured on
1 or 4 mg/1 BAP formed thick tap roots (Fig. IB). The formation of thick tap roots was
correlated with shoot formation. The shoots had short internodes and were branched.
Sometimes more than 10 apical meristems were formed from one embryo (Fig. IB).
Histological studies showed that the thickness of the roots was caused by a loosely
arrangement of cells around the stele (Fig. 1C). Embryos cultured on 0.1 mg/1 BAP formed
thin and slender taproots (Fig. ID). Thin root formation was not always associated with
shoot formation, however, the shoots formed had normal internodes and only one or two
apical meristems (Fig. ID).
The relation between moisture loss and embryo germination.
In the earlier experiment on the effect of different desiccation methods 88% of the Petri-dish
desiccated embryos cultured on 1 mg/1 BAP germinated. In the experiment presented in
Table 1 the same treatment gave a germination of 14 percent. A reason for this difference
in frequency of germination might be the amount of moisture loss, respectively 40 and 20
percent. To test this hypothesis embryos of Adira 4 and Gading were subjected to treatments
which gave different levels of moisture loss. The results are presented in Table 2.
Embryos of both genotypes with a moisture loss of 20% did not germinate into complete
plants after culture on a growth regulator free medium. Germination occurred if embryos
were cultured on a medium with BAP. For Gading this frequency was still very low, but
45 % of the Adira 4 embryos cultured on 1 mg/1 BAP germinated. In both genotypes embryos
with a moisture loss of 40 % gave a higher percentage of germination. For Gading 0.1 mg/1
BAP gave the best germination (72%) and for Adira 4 this was 1 mg/1 BAP (87%). With
higher BAP concentrations there was a shift from germination to shoot formation without
roots.
95
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In both genotypes complete plant germination decreased when embryos had lost 75%
moisture (Table 2). Also in this experiment thick roots and stems with multiple shoots were
produced in the higher BAP concentration. In the next section a method is described which
decreases the need for using high BAP concentrations.
Influence of light/dark conditions on development of normal plants from somatic
embryos. NAA and 2,4-D induced embryos of four genotypes were compared for their
ability to germinate. Undesiccated embryos, both 2,4-D and NAA induced, cultured for 14
days on a medium with 0-4 mg/1 BAP, did not germinate or formed only shoots or roots
(results not shown). Also, after 28 days germination or root formation alone did not occur
and only shoots were formed at a very low frequency (< 10%). The embryos lost between
38 and 53% of their fresh weight.
Desiccated, NAA induced, embryos of TMS90853 (Fig. 2A), Gading (Fig. 2B) and Line 11
(Fig. 2C) germinated at much higher frequencies than 2,4-D induced embryos. This was
observed independent of the light/dark conditions and the used BAP concentration in the
germination medium. For Adira 4 (Fig. 2D) only the NAA embryos cultured on 0 and 0.1
mg/1 BAP germinated at a higher frequency than 2,4-D embryos and on a medium with 1 and
4 mg/1 BAP there were no differences.
In all four genotypes NAA embryos cultured in the dark showed the highest percentage of
germination in media supplemented with 0 or 0.1 mg/1 BAP and this was higher than in the
comparable treatments in the light. Under dark conditions root development occurred within
4 days followed by the elongation and curvature of the hypocotyl and finally the opening of
the hypocotylar hook after 10 days. The stems of the shoots were slender with long
internodes. Embryos cultured in the dark on 0 or 0.1 mg/1 BAP formed mostly single shoots
(Fig. 3A) whereas those on 1 mg/1 BAP formed mostly two apical meristems (Fig. 3B). The
shoots were etiolated which was corrected after one week transfer to the light. In all four
genotypes NAA induced embryos cultured in the light showed the highest percentage of
germination on a medium supplemented with 1 or 4 mg/1 BAP and this was higher than in
the comparable treatments in the dark. Root formation occurred within 4 to 8 days after
culture and shoots followed a few days later. Shoots of NAA embryos cultured in the light
99
on 0.1 mg/1 BAP had mostly one or two apical meristems (Fig. ID) whereas those cultured
on 1 mg/1 BAP had more than 4 apical meristems and sometimes a higher number up to 10
(Fig. IB.). Germination of 2,4-D embryos was very low in TMS 90853 (Fig. 2A), Gading
(Fig. 2B) and Line 11 (Fig. 2C) both in the light and the dark. In Adira 4 (Fig. 2D) 40%
to 50% of the embryos cultured in the light on medium with 1 or 4 mg/1 BAP germinated.
This was higher than in the comparable treatments in the dark. Desiccation of 2,4-D embryos
had a clear effect on root development in all genotypes.
The roots appeared after 4 to 7 days of culture and the form was dependent on the light/dark
conditions; predominantly adventitious in the light (Fig. 3C) and predominantly taproots in
the dark (Fig. 3D). The results presented in Fig. 2 were taken 14 days after culture for
germination. Two more weeks of culture gave only a significant increase of germination for
NAA embryos cultured in light. There was no or only a small improvement of germination
for NAA embryos cultured in the dark and for 2,4-D embryos cultured in the light or the
dark.
DISCUSSION.
Morphological and biochemical evidence has shown that somatic embryogenesis mimics
zygotic embryogenesis in planta (Amirato, 1983). In planta zygotic embryos undergo
desiccation during maturation. Desiccation terminates the developmental process of embryo
formation and activates the switch from maturation to germination (Kermode, 1990). Similar,
in somatic embryogenesis desiccation improves germination of somatic embryos. This was
reported for the first time for cassava by Mathews et al., (1993). In their method 85% of the
desiccated MCol.1505 embryos germinated into complete plants, compared to less than 5%
in non-desiccated embryos. In their study, embryos were induced on solid medium
supplemented with 2,4-D. In our study embryos induced in liquid medium were used and a
comparison was made between embryos induced by NAA or 2,4-D. NAA induced embryos
indeed required desiccation for normal germination, however, to be effective cytokinins were
needed in the medium to germinate desiccated embryos. In auxin induced embryos cytokinins
are known to organise the shoot apex during embryo maturation (Amirato, 1983) and to
break dormancy in poorly germinating somatic embryos (Gray and Puhit, 1991).
100
GERMINATION l:-:>:y SHOOTS GERMINATION ED
90
80
70
60
50
40
30
20
10
B
D
• L
N A A
D
In L
• H D L L
D I D L
2 . 4 - D
D L D L D L
BA CONCENTRATION (mj/1) BA CONCENTRATION <mg/I)
GERMINATION E M 3 SHOOTS
0 .1 1.0 4 . 0 0 0.1 1.0
BA CONCENTRATION <m«/l>
GERMINATION I :- -: I SHOOTS
BA CONCENTRATION <mj/l)
Figure 2: Germination and shoot development of desiccated NAA and 2,4-D induced embryos of
TMS90853 (A), Gading (B), Line 11 (C) and Adira 4 (D) cultured in the dark (D) and the light (L)
on a medium supplemented with 0-4 mg/1 BAP (24-30 mature embryos per treatment).
101
Figure 3: Influence of light/dark regimes on germination of desiccated Gading embryos: NAA/dark
cultured on 0.1 mg/1 BAP: one apical meristem per embryo (A); 2,4-D/light: adventitious roots (B);
NAA/dark cultured on 1.0 mg/1 BAP: one or two apical meristems per embryo (C); 2,4-D/dark: tap
roots (D).
102
Of the cytokinins tested in cassava, BAP improved germination or shoot development of
embryos more than TDZ and kinetin. BAP stimulated both taproot formation and shoot
formation. This is in contrast with multiplication of stem cuttings where 0.1 mg/1 BAP
already inhibits adventitious root formation (Raemakers, 1993).
The BAP concentration needed for high frequency germination seemed to be dependent on
the level of moisture loss in the somatic embryo. If this is optimal, lower levels of BAP are
needed than if it is suboptimal. High concentrations of BAP had distinct effects on the
morphology of the resulting seedling. The BAP concentration required for embryo germi
nation in the dark is lower than in the light and as a consequence the shoots resembled more
the morphology of seedlings of zygotic embryos. A disadvantage was the etiolated nature of
the plants. More research is needed to determine the minimum period of darkness required
to stimulate germination to stimulate germination.
In this study desiccation of 2,4-D induced embryos did not stimulate germination in three of
the four genotypes, but had only a positive effect on root formation. This response was not
affected by the light/dark conditions during culture for germination. However, in the light
predominantly adventitious roots and in the dark taproots were formed. The results described
here with 2,4-D induced embryos are in contrast with those described by Mathews et al.,
(1993) and by Raemakers et al., (1993b,c) previously. It was shown that embryos formed
in liquid medium supplemented with 8 mg/1 2,4-D do not possess a root meristem
(Raemakers, 1993). Culture of these embryos on a medium with BAP, without desiccation
stimulated shoot formation without roots (Raemakers et al., 1993b,c). It seemed that
desiccation of 2,4-D induced embryos triggered the development and the subsequent
outgrowth of a root meristem. This process might have been on the expense of shoot
development. The way 2,4-D embryos were induced by Mathews et al., (1993) differed from
this study. In their study the 2,4-D exposure time was shorter, the concentration was lower
and the embryos were transferred to charcoal supplemented medium for maturation. This
culture system might have resulted in mature embryos with an active root meristem which
easily can be activated and as a consequence shoot formation was not inhibited.
In the procedure described by Mathews et al., (1993) 4 steps were needed (induction,
103
maturation, desiccation of embryos and culture of embryos for germination). This has been
reduced to three steps in the procedure described in this report. It is further an advantage that
the embryos are induced in liquid medium. Compared to solid media, liquid media reduce
labour and improves production. Seedlings are produced 4 weeks after start of a new cycle
of embryogenesis compared to 10 weeks in the method of Mathews et al., (1993). The
described procedure of germination makes somatic embryogenesis further competitive with
the classical method of multiplication by stem cuttings.
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REFERENCES
Amirato, P.V. 1983. Embryogenesis. In: Evans, D.A., Sharp, W.R., Amirato, P.V., and Yamada, Y. (Eds). Handbook of Plant Cell Culture Vol. 1 Macmillan, New York. P: 506.
Anonymous, 1993. FAO Yearbook 1992, Rome. P: 281.
Bocks, K.R., and Woods, R.D. 1983. Etiology of African Cassava Mosaic Disease. Plant disease 67: 994-995
Byrne, D. 1984. Breeding cassava In: Janick J (Eds) Plant Breeding Reviews, Vol 2, AVI Westport CT, USA. P: 73-134.
Cock, J.H. 1985. Cassava: New Potential for a neglected crop. Wetview Press, Boulderand London. P:191.
Gray, D.J., and Purohit, A. 1991. Somatic embryogenesis and development of synthetic seed technology. Critical Reviews in Plant Sei. 10(1): 33-61.
Kartha, K.K., and Gamborg, O.L. 1975. Elimination of cassava mosaic disease by meristem culture. Phytopathology. 95 (7): 826-828.
Kermode, A.R. 1990. Regulatory mechanisms involved in the transition from seed development to germination. Critical Reviews in Plant Sei. 9: 155-195.
Mathews, H., Schöpke, C , Carcamo, R., Chavarriaga, P., Fauquet, C , and Beachy, R.N. 1993. Improvement of somatic embryogenesis and plant recovery in cassava. Plant Cell Rep. 12:328-333.
Murashige, T., and Skoog, F. 1962. A revised medium for rapid growth and bioassay with tobacco cultures. Physiologum Plantarum 15:473-494
Parrot, W.A., Merkle, S.A., and Wiliams, E.G. 1991. Somatic embryogenesis: potential for use in propagation and gene transfers systems. In: Murray, D.R. (Eds) Advanced methods in plant breeding and biotechnology. CAB Int. Wallingford, Oxon 0X10 8DE UK. P: 158-200.
Raemakers, C.J.J.M. 1993. Primary and cyclic somatic embryogenesis in cassava Manihot esculenta Crantz- PhD Thesis, Agricultural University Wageningen, The Netherlands, P:119.
Raemakers, C.J.J.M., Bessembinder, J., Staritsky, G., Jacobsen, E., and Visser, R.G.F. 1993a. Induction, germination and shoot development of somatic embryos in cassava. Plant Cell Tissue and Organ Culture. 33:151-156.
Raemakers, C.J.J.M., Amati, M., Staristsky, G., Jacobsen, E., and Visser, R.G.F. 1993b. Cyclic somatic embryogenesis and plant regeneration in cassava. Annals of Bot. 71:289-294
Raemakers C.J.J.M., Schavemakers, CM. , Jacobsen, E., and Visser, R.G.F. 1993c. Improvement of cyclic somatic embryogenesis of cassava (Manihot esculenta Crantz). Plant Cell Rep. 12: 226-229.
Smith, M.K., Biggs, B.J., and Scott, K.J. 1986. In vitro propagation of cassava {Manihot esculenta Crantz). Plant Cell Tissue and Organ Culture 6:221-229.
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Soenarjo, R., Poespodarsono, S., and Nugroho, J. H. 1987. Cassava Breeding and Agronomy Research in Asia. Proceeding of Regional Workshop held in Ryong, Thailand, Oct.26-26, 1987. P:27-33.
Stamp, J.A., and Henshaw, G.G. 1982. Somatic embryogenesis in cassava. Zeitschrift für Pflanzenphysiologie 105:183-187.
Stamp, J.A., and Henshaw, G.G. 1987. Secondary somatic embryogenesis and plant regeneration in cassava. Plant Cell Tissue and Organ Culture. 10:227-233.
Szabados, L., Hoyos, R., and Roca, W. 1987. In vitro somatic embryogenesis and plant regeneration of cassava. Plant Cell Rep. 6:248-251.
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CHAPTER 7
GENERAL DISCUSSION
107
Somatic embryogenesis and regeneration in cassava
In figure 1 an overview of somatic embryogenesis in cassava is given. Until 1993 systems
with only primary and secondary somatic embryogenesis were well developed. Somatic
embryogenesis starts with the induction of embryos from primary expiants. Recently it was
shown that besides zygotic embryos (Stamp and Henshaw, 1982) and young leaf expiants
(Stamp and Henshaw, 1987; Szabados et al., 1987; Raemakers et al., 1993) also floral tissue
has the capacity to undergo primary embryogenesis (Mukherjee, 1995). Primary embryos
derived from both leaf expiants and zygotic embryos form secondary somatic embryos and
continuous cultures are obtained by cyclic culture of embryos on auxin supplemented
medium. In all these reports mostly Murashige and Skoog (1962) medium supplemented with
2,4-D was used to initiate primary and secondary somatic embryogenesis. It was shown by
Sudarmonowati and Henshaw (1992) that also Picloram and Dicamba have this capability.
ma tue leaves > ms+2,4-d > embryos'
desiccation
culture in dark
seedlings
maturation
immature embryos
selection of friable embryos
friable embryos
Figure 1: Schematic representation of somatic embryogenesis in cassava, including primary, secondary somatic embryogenesis, selection of friable embryogénie callus, maturation and desiccation followed by germination.
gd2= medium supplemented with Gresshoff and Doy salts (1974) and vitamins plus 20 g/1 sucrose. gd4= medium supplemented with Gresshoff and Doy salts (1974) and vitamins plus 40 g/1 sucrose. ms2= medium supplemented with Murashige and Skoog salts and vitamins plus 20 g/1 sucrose. pic= 10 mg/1 Picloram, NAA= 10 mg/1 naphthalene acetic acid, 2,4-D = 8 mg/1, 2,4-dichlorophenoxy acetic acid. sh6= medium supplemented with Schenk and Hildebrandt (1972) salts and vitamins plus 60 g/1 sucrose.
108
As shown in this thesis, NAA can also induce secondary somatic embryogenesis, however
in contrast to Picloram and Dicamba it failed to induce primary embryogenesis (Chapter 2).
NAA induced embryos differed in many respects from 2,4-D induced ones. For example,
histologically, the by 2,4-D newly induced secondary embryos were attached vertically to the
expiants whereas those by NAA were horizontally. Another prominent difference of NAA
compared to 2,4-D induced embryos was the faster maturation. In NAA containing medium
mature embryos are obtained in 14 days, whereas in 2,4-D it required a minimum of 21
days. Shortening the culture duration has a beneficial effect, particularly, when operating on
a large scale.
For many genotypes and in several laboratories there is still a problem in obtaining
embryogénie cultures of cassava (Mroginski and Scocchi, 1992; Taylor et al., 1992;
Narayanaswamy et al., 1995; Sudarmonowati and Bachtiar, 1995). The main problem is not
that embryogénie tissue from primary expiants can be obtained, but the large scale
multiplication of this tissue by secondary embryogenesis. For this purpose, either tissue
consisting of immature embryos or mature embryos can be used. Multiplication of immature
embryos is highly genotype dependent (Nigel Taylor, personal communication), while
multiplication of mature embryos is largely genotype independent (Raemakers, 1993; Chapter
3). Both primary and secondary somatic embryogenesis are characterized by the formation
of propagules with a bipolar structure. Therefore, Taylor et al., (1995) proposed the term
organized embryogenesis. Organized cells are defined as a group of actively dividing cells,
having the tissues and organs formed into a characteristic unified whole (Walker, 1989).
A less organized type of somatic embryogenesis was developed by Taylor et al. (1995). With
continuous selection, organized embryogénie tissue cultured on a Gresshoff and Doy (1972)
medium salts and vitamins supplemented with Picloram converted gradually into a less
organized tissue. This tissue consisted of a callus-like mass of pro-embryos which was very
friable. Therefore, this tissue was called friable embryogénie callus (FEC). The cells in FEC
are continuously in a state where they break away from group control and because of that
they are not organized into a unified structure. Suspension cultures were initiated by culturing
FEC in Schenk and Hildebrandt (1972) medium supplemented with 6 % (w/v) sucrose and
10 mg/1 Picloram. Every 2-3 days this medium was refreshed. Maturation of friable
109
embryos was accomplished by transferring FEC to maturation medium (Chapter 4, 5).
Mature embryos could be induced into secondary somatic embryogenesis by culturing on
Murashige and Skoog (MS) medium supplemented with auxins.
Primary and secondary somatic embryogenesis are relatively easy to establish in a wide range
of genotypes (Chapter 2), while FEC is for the time being restricted to a few genotypes. The
prospect of FEC for a new system of somatic embryogenesis and genetic transformation is
promising, although further research is needed to make this system applicable to more
genotypes. Essential for this process is the availability of high quality organized tissue and
the ability of this tissue to convert into FEC. Taylor et al. (1995) "used organized tissues"
which were multiplied at the immature state to initiate FEC. In this case two steps (initiation
of organized tissue and conversion into unorganized tissue) are determinative for the
successful initiation of FEC. Both steps are genotype dependent. If organized tissue is
multiplied in the mature state as described by Raemakers et al., (1993) then only the ability
of this tissue to convert into FEC is a determinative step to initiate FEC. It remains to be
investigated whether or not organized tissue can be used as starting material. If organized
tissue cannot be used, then this tissue should be first multiplied in the immature state before
it can be used to initiate FEC. In chapter 2 it is shown that this readily can be accomplished.
Either by culturing expiants at a high density or by reducing the cyclic duration.
Regeneration of protoplasts
Protoplasts isolated from leaf mesophyll cells and somatic embryos of different genotypes
developed readily into green callus. The callus occasionally formed roots, but not shoots or
embryos (Chapter 3). In rice (Toriyama et al., 1985), maize (Rhodes et al., 1988; Lyznik
et al., 1989), white spruce (Attree et al., 1989) and coffee (Acuna and Pena, 1991)
regeneration of plants from protoplasts was achieved after using suspension cultures as
starting material. Also in cassava protoplasts isolated from suspension cultures obtained from
friable embryogénie callus were capable of regenerating into plants (Chapter 4). The yield
of protoplasts isolated from FEC was four-fold higher as compared to that from somatic
embryos and leaf mesophyll cells. It was shown that the callus derived from these protoplasts
behaved as the original material: culture on maturation medium leaded to maturation of
friable embryos, culturing of friable callus on GD2 or SH6 leaded to proliferation of FEC
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and culturing of mature embryos on auxin supplemented medium to secondary somatic
embryogenesis (Fig. 1).
Transformation of cassava
Transformation in higher plants can be defined as the process of introduction and expression
of a foreign gene or genes in a genome other than by sexual crossing (Visser, 1989). Two
types of gene transfer techniques are mainly employed in plant genetic engineering. One is
mediated by Agrobacterium spp. (Potrykus et al., 1985). In this method a vector, A.tumefaci-
ens often is used. The success of transformation relies in large part on the ability of the
bacterium to transfer DNA to the cells. The other method, known as direct gene transfer, is
free of a vector. There are different direct gene transfer techniques available. The two most
commonly used are particle bombardment or biolistic delivery (Sanford, 1988) and
electroporation (Fromm et al., 1986).
(J). Agrobacterium-mediated transfer of DNA
In the past, five strains of A.tumefaciens have been tested on secondary somatic embryos of
cassava. The strain AM 8706 formed readily blue spots resulting from the transient
expression of GUS. Occasionally this resulted in chimeric transformed embryos. In one case
an embryo was obtained with a transformed primary root (Raemakers-unpublished). Cabrai
et al., (1995) have identified a strain of Agrobacterium spp. that is more virulent to cassava.
Transformation of secondary somatic embryos with this wild type strain had resulted in some
putative transformed plants. It remains to be investigated whether this wild type strain can
be converted into a useful plant vector.
(2). Particle bombardment
Secondary somatic embryos induced by NAA or 2,4-D have been treated by particle
bombardment. In both cases this resulted in chimeric transformed embryos (Chapter 2).
However, it was not possible to enlarge the transformed sectors by a new cycle of
embryogenesis. Essentially the same results were reported by Fauquet et al., (1992) and
Cabrai et al., (1995). The nature of somatic embryogenesis in FEC is different from
secondary somatic embryogenesis as described by Raemakers (1993). The main difference
concerned, the basic origin of new embryos. In FEC it was claimed to be at the surface of
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the embryogénie units (Taylor et al., 1995) so that they are more accessible for gene-
transformation. Particle bombardment of FEC resulted in stable transformation (Chapter 5).
The transformed nature of FEC and of transformed plants was confirmed by PCR and
Southern Blot analysis, respectively. Machine parameters which influence the momentum of
the particles were not determinative. The physiological state of the material was more crucial
for successful transformation. For this purpose, attention must be paid in culturing a good
quality of suspensions. Two to three week-old suspension cultures were found to be the best
for transformation. Under the conditions that these suspension cultures are competent for
regeneration, transformation will be enhanced. Finally more attention must be paid to the
post-transformation environment.
(3). Electroporation
Electroporation of chopped secondary embryos resulted in transient GUS activity. However,
also this technique did not result with the used expiants in stably transformed somatic
embryos (Luong et al., 1995). Electroporation of FEC might be an alternative option for
successful plant transformation.
Electroporation of protoplasts is one of the direct gene transfer techniques that produced
transgenic plants in many important cultivated plant species (see Bajaj, 1989a; 1989b; 1993).
This technique was applied by us in cassava using protoplasts isolated from young leaves.
Although in a low frequency, it resulted in transformed callus (Chapter 3-results not shown;
LUC positive). This transgenic callus was not capable of regenerating into plants. The
presence of competent cells for regeneration was the key step in establishing a transformation
system. Protoplasts isolated from FEC have the capability to regenerate into plantlets
(Chapter 4). Combination of these two results can lead to a much better transformation
procedure.
Barrier to cassava transformation
The described transformation procedure in Chapter 5 needs to be improved especially with
respect to maturation and germination of mature embryos into plants. The same problems
were observed with FEC derived from protoplasts. Maturation of friable embryos was not
studied thoroughly. However, an improved procedure for germination of mature embryos is
described in Chapter 6. It was shown that desiccation followed by culturing in darkness with
112
a low BAP concentration increased germination of NAA induced embryos in all tested
genotypes. The same procedure was not successful for 2,4-D induced embryos. This positive
effect of NAA on germination can not be used directly for mature embryos derived from
FEC or protoplasts, because 2,4-D was more efficient than NAA in inducing secondary
embryogenesis. However, after one cycle of secondary embryogenesis NAA was also highly
efficient in inducing secondary embryogenesis (data not shown) and than these embryos
should be used for germination.
Genotype dependency has been reported for both the gene transfer technique and the ability
to regenerate. Transformation competence of Lycopersicon peruvianum is higher than in
cultivated tomato L. esculentum (Koornneef et al., 1986). This was also observed for
different genotypes of potato (El Kharbotly, 1995). At this moment FEC is established for
a few cassava genotypes, and it remains to be determined whether FEC also can be
established in other genotypes. It might be the case that a genotype which is bearing useful
traits is recalcitrant to transformation, while a genotype with less importance is more
amenable. The possible strategy to overcome these problems is transformation followed by
sexual crossing and conventional breeding. Embryo rescue can help to increase the low
frequency of germination of cassava seeds. Multiplication of the transformed seedling by
micropropagation will not be a serious problem because this work is a routine procedure for
almost every laboratory. A more serious problem for developing countries is to establish
alternative methods for selection of transformed tissues. In chapter 5 selection of transformed
tissues was based on the activity of the luciferase gene. Unfortunately the equipment to detect
LUC activity is relatively expensive. Selection based on antibiotics like kanamycin (reviewed
by Nap et al., 1992), or herbicides like L-phosphinotricin (De Block et al., 1987) seem to
be suitable alternatives.
Prospect of gene transformation in cassava
Application of plant gene technology encompasses a multitude of different techniques ranging
from isolation of useful genes, their characterization and manipulation, to the reintroduction
of modified constructs into the plants (Lonsdale, 1987). Plant gene technology will catalyze
progress in plant breeding, as will be exemplified by a few examples of transgenic crops like
113
rice (Chen et al., 1987; Shimamoto et al., 1989), maize (Gordon-Kamm et al., 1990; Vain
et al., 1993), wheat (Marks et al., 1989), and potato (De Block, 1988; Visser et al., 1989).
Rapid progress in gene technology has allowed insight into the complex molecular mechanism
of plant pathogen recognition and the natural defence strategies of host plants. This
technology can also be used for controlled and efficient identification of desirable genotypes,
far beyond the possibilities of classical breeding.
Successful attempts have been made to improve resistance against pathogenic viruses like
tobamovirus in tobacco (Powel Abel et al., 1986), potexvirus in potato (Hoekema et al.,
1989) and in papaya (Fitch et al., 1992). In the above examples the introduced trait was
based on the expression of single genes that are coding for the coat protein. In cassava,
African cassava mosaic virus (ACMV) and cassava common mosaic virus (CCMV) might
be controlled by the coat protein-mediated resistance technique (Fauquet et al., 1992). The
genes encoding key enzymes of cyanogenesis have been cloned (Hughes et al., 1994) which
makes manipulation of cassava cyanogenesis possible by genetic transformation using the
antisense approach.
114
REFERENCES
Acuna, R.J., andPena, M. 1991. Plant regeneration from protoplasts of embryogénie cell suspensions of Coffea arabica L. cv. Caturra. Plant Cell Rep. 10:345-348.
Attree, S.M., Dunstan, D.I., and Fowke, L. 1989. Initiation of embryogénie callus and suspension cultures, of white spruce (Picea glaucu). Can.J.Bot.67:1790-1795.
Bajaj, Y.P.S. 1989a. Plant protoplasts and genetic engineering 1. In: Biotechnology in Agriculture and Forestry Vol 8. Springer-Verlag, Berlin. P:444.
Bajaj, Y.P.S. 1989b. Plant protoplasts and genetic engineering 11. In: Biotechnology in Agriculture and Forestry Vol 9. Springer-Verlag, Berlin. P:499.
Bajaj, Y.P.S. 1993. Plant protoplasts and genetic engineering 111. In: Biotechnology in Agriculture and Forestry Vol 22. Springer-Verlag, Berlin. P:332.
Cabrai, G.B., Bautista, L. de O., De Andrade, G.M., Rech, E.L., and Brasileiro, A.C.M. 1995. Cassava transformation by Agrobacterium tumefaciens and particle bombardment. The Cassava Biotechnology Network. Proceedings of the Second International Scientific Meeting. Bogor, Indonesia, 22-26 August 1994. P:264-275.
De Block, M., Botterman, J., Van de Wiele, M., Dockx, J., Thoen, C , Gossele, V., Rao Movva, N., Thompson, C , Van Montagu, M., and Leemans, J. 1987. Engineering herbicide resistance in plants by expression of detoxifying enzyme. The EMBO Journal. 6:2513-2518.
De Block, M. 1988. Genotype-independent leaf disc transformation of potato {Solanum tuberosum) using Agrobacterium tumefaciens. Theor. Appl. Genetic 76: 767-774.
El Kharbotly, A. 1995. Transposon tagging: Towards the isolation of the resistance R-genes in potato against Phytophthora infestons (Mont.) de Bray. Thesis PhD. Agricultural Wageningen University. P: 99.
Fauquet CM. , Schöpke C , Chavarriaga. P., Sangare. A., and Beachy R.N. 1992. Genetic engineering technologies to control viruses and their application to cassava viruses. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings CBN. First International Scientific Meeting of the Cassava Biotechnology Network. Cartagena. Colombia 25-28 August 1992. P: 190-207.
Fitch, M.M.M., Manshardt, R.M., Gonsalves, D., Slightom, J.L., and Sanford, J.E. 1992. Virus resistant papaya plants derived from tissue bombarded with the coat protein gene of the papaya ring spot virus disease. Bio/Technology 10:1466-1472.
Fromm M. E., Taylor L.P. Walbot V. 1986. Stable transformation of maize after gene transfer by electroporation. Nature 319:791-793.
Gordon-Kamm, W.J., Spencer, T.M., Mangano, M.L., Adams, T.R., Daines, R.J., Start, W.G., O'Brien, J.V., Chambers, S.A., Adams, W.R., Willets, N.G., Rice, T.B., Mackey, C.J., Krueger, R.W., Kausch, A.P., and Lemaux, P.G. Transformation of maize cells and regeneration of fertile transgenic plants. Plant Cell 2:603-618.
Gresshoff, P.M., and Doy, C.H. 1974. Development and differentiation of haploid Lycopersicon
115
esculentum (tomato). Planta 107:161-170.
Hoekema , A., Huisman, M.J., Molendijk, L., van den Elzen, P.J.M., Cornelissen, B.J.C. 1989. The genetic engineering of two commercial potato cultivars for resistance to potato virus X. Bio/Technology 7:273-278.
Hughes, J., de Carvalho, C , Francisco, J.P., and Murray, B.S. 1994. Purification, characterization and cloning of a-hydroxynitrile lyase from cassava (Manihot esculenta Crantz). Arch. Biochem. Biophys. 311:496-502.
Koornneef, M., Hanhart, C , Jongsma, M.( Toma, I., Weider R., Zabel,P., and Hille, J. 1986. Breeding of a tomato genotype readily accessible to genetic manipulation. Plant Sei. 45:201-208.
Lonsdale, D.M. 1987. The molecular biology and genetic manipulation of the cytoplasm of higher plants. In: Rigby, P.W.J (Eds). Genetic Engineering 6. Academic Press. London-Orlando. P:48-95.
Lyznik, L.A., Kamo, K.K., Grimes, H.D., Ryan, R., Chang, K.L., and Hodges, T.K. 1989. Stable transformation of maize: the impact of feeder cells on protoplast growth and transformation efficiency. Plant Cell Rep. 8:292-295.
Marks, M.S., Kemp, J.M., Woolston, C.J., Dale, P.J. 1989. Agroinfection of wheat: a comparison of Agrobacterium strains. Plant Sei. 63 (2):247-256.
Mathews, H., Schöpke, C , Carcamo, R., Chavarriaga, P., Fauquet, C , and Beachy, R.N. 1993. Improvement of somatic embryogenesis and plant recovery in cassava. Plant Cell Rep. 12:328-333.
Mroginski and Scocchi, 1992. Somatic embryogenesis of Argentine cassava varieties. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings First Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P: 175-179.
Mukherjee, A. 1995. Embryogenesis and regeneration from cassava calli of anther and leaf. The Cassava Biotechnology Network. Proceeding of the Second International Scientific Meeting. Bogor,Indonesia, 22-26 August 1994. P:375-377.
Murashige, T., and Skoog, F. 1962. A revised medium for rapid growth and bioassay with tobacco cultures. Physiologum Plantarum. 15:473-497.
Nap, J.P., Bijvoet, J., and Stiekema, W. 1992. Biosafety of kanamycin-resistant transgenic plants. Transgenic research. 1:239-2249.
Narayanaswamy, T.C., Ramaswamy, N.M., and Sree Rangaswamy, S.R. 1995. Somatic embryogenesis and plant regeneration in cassava. The Cassava Biotechnology Network. Proceeding of the Second International Scientific Meeting. Bogor.Indonesia, 22-26 August 1994. P:324-329.
Potrykus, I. Saul, M. Paskowski, J., and Shillito R.D. 1985. Direct gene transfer into protoplasts of a graminaceous monocot. Mol. Gen. Genet. 199:183-188.
Powel Abel, P., Nelson, R.S., De B, Hoffman, N., Rogers, S.G., Fraalet, R.T., Beachy, R. 1986. Delay of disease development in transgenic plants that express the tobacco mosaic virus coat protein gene. Science 232:738-743.
116
Raemakers, C.J.J.M. 1993. Primary and cyclic somatic embryogenesis in cassava (Manihot esculenta Crantz). PhD. Thesis. Agricultural University Wageningen. P:119.
Raemakers, C.J.J.M., Amati, M., Staritsky, G., Jacobsen, E., and Visser, R.G.F. 1993b. Cyclic somatic embryogenesis and plant regeneration in cassava. Annals of Bot. 71:289-294.
Rhodes, CA. , Lowe, K.S., and Ruby, K.L. 1988. Plant regeneration from protoplasts isolated from embryogénie maize cell cultures. Bio/Technology. 6:56-60.
Sanford, J.C. 1988. The biolistic process. Trends in Biotechnology. 6:299-302.
Schenk, R.U., and Hildebrandt, A.C. 1972. Medium and techniques for induction and growth of monocotyledonous and dicotyledonous plant cell cultures. Can. J.Bot. 50:199-204.
Shimamoto, K. Terada, R., Izawa, T. and Fujimoto, H. 1989. Fertile transgenic rice plants regenerated from transformed protoplasts. Nature 338: 274-276.
Stamp, J.A. and Henshaw, G.G., 1982. Somatic embryogenesis in cassava. Zeitschrift für Pflanzenphysiologie. 105:183-187.
Stamp, J.A. and Henshaw, G.G., 1987. Secondary somatic embryogenesis and plant regeneration in cassava. Plant Cell Tissue and Organ Culture 10:227-233.
Sudarmonowati. E., and G.G. Henshaw. 1992. The induction of somatic embryogenesis of recalcitrant cultivars using picloram and dicamba. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings First Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P: 128-133.
Sudarmonowati and Bachtiar, 1995. Induction of somatic embryogenesis in Indonesian cassava genotypes. The Cassava Biotechnology Network. Proceeding of the Second International Scientific Meeting. Bogor,Indonesia, 22-26 August 1994. P:364-374)
Szabados L., Hoyos R. and Roca W. 1987. In vitro somatic embryogenesis and plant regeneration of cassava. Plant Cell Rep. 6:248-251.
Taylor, N.J., Clarke, M., and Henshaw, G.G. 1992. The induction of somatic embryogenesis in fifteen African cassava cultivars. In: Roca, W.M., and Thro, A.M. (Eds). Proceedings First Scientific Meeting of the Cassava Biotechnology Network. Cartagena, Colombia 25-28 August 1992. P:134-137.
Toriyama, K. and Hinata, K. 1985. Cell suspensions and protoplasts culture in rice. Plant Sei. 41:179-183.
Vain, P., McMullen M.D. and Finer J.J. 1993. Osmotic treatment enhances particle bombardment-mediated transient and stable transformation of maize. Plant Cell Rep. 12: 84-88.
Visser R.G.F. 1989. Manipulation of the starch composition of Solanum tuberosum L. using Agrobacterium rhizogenes mediated transformation. PhD Thesis. Rijksuniversiteit Groningen. P: 143.
Visser R.G.F., Jacobsen E., Hesseling-Meinders A., Schans M.J., WitholtB., FeenstraW.J. 1989. Transformation of homozygous diploid potato with an Agrobacterium tumefaciens binary vector
117
system by adventitious shoot regeneration on leaf and stem segments. Plant Mol. Biol. 12: 329-337.
Walker, P.M.B. 1989. Chambers Biology Dictionary. W&R Chamber Ltd. Clay Ltd, St. Ives Pic. England. P:205.
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SUMMARY
Cassava (Manihot esculenta Crantz) is a tropical tuber crop with unique properties. It is predominantly grown because of its starchy roots. Also in Indonesia, where it is known as 'ubi kayu' or 'singkong', it is an important crop. Until the middle of the 1960's, cassava was the major food security crop in rural areas of some provinces in Indonesia. Nowadays, cassava is an alternative crop for co-staple food and a substitutive crop when other crops fail. Even on marginal soils or cultivated with minimum tillage, cassava is one of the best carbohydrate producers. Large portions of cassava are used for animal feed and in starch based industries and are exported to the European Community and Japan. Local demand for fresh cassava for human consumption and for the agro-industry is increasing. Due to a large number of problems further use and expansion of cassava is restricted. One of these problems concerns the rather low yield of the crop. Although yield of over 90 tons/hectare have been reported the yield is rarely exceeding 12 tons/hectare. To some extent this can be attributed to the absence of fertilizer during growth. Another important factor is the susceptibility to all kind of pests and diseases, which is enhanced by the fact that farmers produce, by vegetative propagation, their own planting material. In wet regions like Western-Java or Sumatra Cassava Bacterial Blight is a serious disease, while in dry regions infections by red mites are a threat to the harvest. For human consumption it is necessary to have genotypes with a low cyanide content. Furthermore, the industry needs cassava cultivars especially suited for high starch production and adapted to mechanical harvest methods. At an international level, cassava breeding programmes have responded to ever changing situations. However, breeding programmes are time consuming and difficult because cassava is considered a 'poor man's crop' and thus little research efforts have been directed towards improvement of this important crop. The fact that cassava is a vegetatively propagated, cross breeding allotetraploid crop did not help either. As of 1980 a number of breeding programmes have been initiated amongst others by the Central Institute for Food Crops of the Agency for Agricultural Research and Development (Indonesia) to synthesize better performing genotypes. Because it takes 10 to 15 years to introduce a new variety on the market it is imperative that breeders make use of all available means to obtain these better genotypes. By implementing in vitro multiplication mass clonal propagation of improved varieties can be applied, while genetic modification (by which genes of interest can be transferred into cassava) opens possibilities to add or alter traits which cannot easily be achieved by traditional breeding alone.
This thesis deals with an investigation of several aspects of regeneration and transformation of cassava. The aim was to develop a routine procedure for genetic modification of cassava. In Chapter 1 a general overview is given of those aspects which are determinative in
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obtaining successful transformation. Furthermore the available methods of regeneration and their unsuitability to be combined with transformation is discussed. Cassava transformation requires an efficient and reliable regeneration system which can be combined with a gene transformation system. Previously, a regeneration system was developed in which somatic embryos produced new embryos in a cyclic fashion. Considerable efforts to combine this system with a transformation technique had failed. With this system only chimeric transformed embryos were formed. One of the reasons for this was the way in which the embryos developed. When using the auxin 2,4-D new embryos developed from deep within the used tissue. When using another auxin (NAA) it was not possible to obtain primary somatic embryos, but when secondary or cyclic somatic embryos were used this auxin gave rise to the formation of new embryos from the (sub)epidermis. However, this change did not lead to completely transformed embryos either (Chapter 2). The use of NAA had a distinct positive effect on the speed and frequency with which new embryos could be obtained.
As mentioned in Chapter 1 somatic embryogenesis proved to be the only repeatable and efficient way of regeneration available in cassava. In Chapter 3 experiments are described in order to develop a protoplast regeneration system. Previously only leaves or stems were used as source for protoplasts. In Chapter 3 the results of using leaves, but more importantly using somatic embryos as protoplast source are described and compared. The rational behind it is the assumption that protoplasts isolated from somatic embryos might have a higher regeneration capacity as compared to protoplasts isolated from leaves. Different compositions of growth regulators were tested at subsequent stages of culture. None of the tested protocols resulted in regeneration. However, protoplasts isolated of both somatic embryos and leaf mesophyll expiants of several genotypes formed readily green callus. Root formation was observed in a few cases, but shoots were never formed. The failure to obtain plants from protoplasts was either due to incompetence of protoplasts to regenerate or to inappropriate media compositions or a combination of both factors.
In Chapter 4 a, for cassava, new somatic embryo culture system based on so called friable embryogénie callus or suspension culture (FEC) is introduced. This was developed by Dr. N. Taylor of the University of Bath in the United Kingdom. This system differs in many respects from the previous system of somatic embryogenesis. Friable embryogénie callus (FEC) occurs almost always in the form of pre-globular embryogénie units with sizes of less than 1 mm. FEC has a high proliferation rate and originates from surface cells of these pro-embryos and (in most cases) from one single cell. Efforts were made to set up a protoplast regeneration system by using FEC as the source for protoplasts. The procedures of protoplast isolation from somatic embryos (Chapter 3) were applied to suspension cultures derived from FEC. Changes were made with respect to the medium composition for the first step in
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culturing protoplasts. The first culture period required at least three to four weeks for the induction of cell divisions and development of microcalli. After two months of culture up to 60% of these calli were 'friable'. For maturation of friable embryos, FEC was transferred to maturation medium for two months. Finally, development of shoots was performed by culturing mature embryos on MS2 supplemented with 1 mg/1 BAP. Shoots developed after at least four weeks of incubation on this germination medium, but only 30% of the mature embryos germinated.
Because in FEC the new pro-embryos are derived from single cells at the surface of the existing embryogénie units, they were used as starting material for direct gene transfer by particle bombardment (Chapter 5). The FEC of genotype TMS60444 was bombarded with DNA constructs harboring the firefly luciferase gene. This gene, normally not present in plant material, is capable of emitting light which can be detected by a luminometer (a camera highly sensitive for light emission). Machine parameters such as the distance between the target cells and DNA-macro-carrier and the strength of velocity were not determinative. The quality of starting material was crucial for successful transformation. FEC cultured for at least a week in liquid SH6 medium was found to be the best target tissue for transformation. Selection of transient and stably transformed FEC was based on the activity of the firefly luciferase gene. Friable embryos containing only one spot with luciferase activity were subcultured in either liquid or on solid medium. After 8 weeks transformed FEC cultured in liquid medium increased almost fivefold, and in solid medium almost threefold. Friable embryos of cultures containing at least 1% transformed material were cultured for maturation. Transformed mature somatic embryos were multiplied by cyclic somatic embryogenesis before they were allowed to develop into shoots. The transgenic nature of FEC cultures as well as that of regenerated plants was confirmed by PCR and Southern Blot Analysis, using the luciferase gene as a probe.
The developed transformation procedure is reproducible for the investigated genotype. Major efforts are directed to make the protocol applicable to other genotypes as well, to decrease the duration of time needed to obtain transformed shoots and to increase the efficiency. Important bottlenecks in achieving these goals are: maturation of embryos from the FEC cultures and shoot development of the mature embryos by optimising germination. Because transgenic somatic embryos are in principle clonal of nature, the propagules can be used for mass clonal multiplication. For this application an efficient germination system is a prerequisite. Therefore, the ability of NAA and 2,4-D to obtain shoot conversion is described in Chapter 6. After desiccation, NAA induced embryos germinated in a higher frequency than 2,4-D induced embryos. Cytokinin was required for a high frequency germination. Incubating desiccated embryos in the dark with a low cytokinin concentration
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(0.1 mg/1 BAP) or in light with a higher concentration (1 mg/1 BAP) were comparable in promoting germination. However, they differed in the morphology of the produced shoots and in the germination period of the embryos. If the concentration of BAP was low ( < 0.1 mg/1) an embryo developed into a single shoot, in contrast to a high (1.5 mg/1 or more) concentration where multiple shoots were formed from one embryo.
This thesis is a major step in the establishment of a routine transformation protocol for cassava using particle bombardment. Furthermore it opens an alternative way for transformation by using the described protoplast regeneration system combined with electroporation or PEG mediated DNA transformation. With this method breeding of cassava by using transgenic plants has become possible.
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SAMENVATTING
Cassave (Manihot esculenta Crantz), ook wel manioc of tapioca genoemd, is een zeer belangrijk voedselgewas in de tropen. Het wordt met name geteeld voor de zetmeel bevattende wortelstokken. Ook in Indonesië waar het bekend is onder de namen 'ubi kayu' of 'singkong' wordt het gewas op grote schaal geteeld. Met name op het platteland wordt cassava als een hoofdgewas geteeld wanneer de boeren over onvoldoende geld beschikken om gewassen zoals mais te kunnen telen. Ook wanneer de kwaliteit van de grond slecht is zal de boer in veel gevallen voor cassave kiezen. Cassave is een goedkoop gewas zowel in aanschaf als onderhoud, terwijl het ook nog eens een redelijke oogstzekerheid geeft. Alhoewel cassave nog steeds als 'armeluis' gewas wordt beschouwd neemt de economische betekenis van het gewas, niet alleen in Indonesië, maar ook in andere landen in Zuid-Oost Azië toe. Een groot deel van de cassave productie wordt geëxporteerd als chips of pellets voor de veevoeder industrie naar onder andere Europa. Cassave productie voor lokaal gebruik, voor humane consumptie en als zetmeel bron, wordt steeds belangrijker. Met toenemende industrialisatie en het bereiken van een hogere levensstandaard wordt de betekenis van cassave als zetmeel bron steeds belangrijker. Er is echter een groot aantal problemen die, naast een gebrekkige basale kennis van het gewas, verdere toename van gebruik en toepassingen van cassave in de weg staan.
Een algemeen voorkomend probleem is de relatief lage opbrengst van het gewas. Ofschoon opbrengsten van 90 ton per hectare mogelijk zijn, wordt zelden meer dan 12 ton per hectare gerealiseerd. Voor een deel wordt dit verklaard door de relatief slechte gronden waarop cassave geteeld wordt en het niet gebruiken van kunstmest bij de teelt. Voor een ander deel wordt het verklaard door de vatbaarheid van cassave voor plagen en ziekten dat versterkt wordt doordat de boeren hun plantmateriaal zelf vermeerderen. In natte regio's zoals West-Java en Sumatra is de door een bacterie veroorzaakte ziekte "Cassava Bacterial Blight" een groot probleem, terwijl in droge gebieden aantasting door rode mijten een bedreiging voor de oogst vormt. Voor menselijke consumptie is het noodzakelijk dat het cyanide gehalte laag is. Verder zou men om goed en snel te kunnen oogsten willen beschikken over machinaal oogstbare rassen.
Afhankelijk van het doel dat men nastreeft wil men dus beschikken over superieure cassave genotypen. Traditionele veredeling van cassave is langdurig en moeilijk. Omdat cassave lange tijd beschouwd werd als een onbelangrijk gewas is er relatief weinig veredeld. Dit werd nog eens versterkt door het feit dat cassave, een allotetraploid (twee verschillende genomen die elk twee maal voorkomen) en een, slecht bloeiende, kruisbevruchter is die bij voorkeur vegetatief vermeerderd wordt via stekken. Sinds 1980 zijn er veredelingsprogramma's
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opgestart onder andere bij het Central Institute for Food Crops van het Agency for Agricultural Research and Development (AARD) om goede genotypen te synthetiseren. Vanwege de tijd die het kost om een nieuw traditioneel veredeld ras op de markt te kunnen brengen (10 tot 15 jaar) is het noodzakelijk dat de veredelaars ook gebruik maken van nieuwe technieken om deze rassen te verkrijgen. Hierbij kan gedacht worden aan massale klonale vermeerdering via in vitro technieken en aan genetische modificatie. Genetische modificatie is een techniek waarbij men gericht een eigenschap in een plant kan wijzigen of toevoegen. Dit houdt in dat men, in theorie, het beste ras van dit moment resistent kan maken tegen die ziekte die op dat moment de meeste schade veroorzaakt.
De centrale leidraad van dit proefschrift is het ontwikkelen van een genetisch modificatie systeem voor cassave. Genetische modificatie vereist zeer efficiënte en, bij voorkeur, ras onafhankelijke regeneratie-protocollen die gecombineerd kunnen worden met transformatie. Regeneratie bij planten kan via somatische embryogenese en adventief scheut Organogenese verlopen. In Hoofdstuk 1 wordt een kort overzicht gegeven van de aspecten welke bepalend zijn voor het welslagen van een succesvolle transformatie in het algemeen en dus ook bij cassave. Verder wordt een overzicht gegeven van de beschikbare regeneratie methoden bij cassave en hun (ongeschiktheid om ze te combineren met een transformatie protocol. De enige beschikbare regeneratiemethode -somatische embryogenese- had in eerder onderzoek bij de vakgroep Plantenveredeling (Proefschrift Raemakers, 1993) en ook bij andere onderzoeksinstellingen niet tot volledig getransformeerde planten geleid. Slechts met grote moeite konden er embryos en een enkele scheut verkregen worden die, voor het transgen, chimeer bleken te zijn. Eén van de oorzaken daarvan zou de wijze kunnen zijn waarop de embryos uit dieper gelegen delen van de explantaten ontstaan wanneer ze op embryo inducerend, d.w.z 2,4-D (een auxine) bevattend, medium werden gelegd. Bij het gebruik van een ander auxine (NAA), dat niet in staat was om primaire somatische embryogenese te induceren maar wel secundaire of cyclische embryogenese, bleek de ontstaans wijze van de embryos anders te zijn. De nieuwe embryos werden meer aan de oppervlakte van de explantaten gevormd. Desondanks leidde dit niet tot de vorming van volledig getransformeerde embryos wanneer ze in transformatie experimenten gebruikt werden (Hoofdstuk 2). Wel bleek het gebruik van NAA positieve effecten te hebben op de snelheid en frequentie waarmee nieuwe embryos werden verkregen (Hoofdstuk 2).
Zoals gemeld bleek somatische embryogenese de enige wijze te zijn waarop regeneratie kon plaats vinden. Hoofdstuk 3 beschrijft de resultaten van experimenten die erop gericht waren om uitgaande van protoplasten, die uit blad en somatische embryos verkregen werden, tot plant regeneratie te komen. De verwachting was dat protoplasten van somatische embryos wellicht een beter regeneratief vermogen zouden hebben dan protoplasten uit blad en derhalve
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in staat zouden moeten zijn om tot planten te regenereren. Dit bleek niet het geval te zijn. Ontwikkeling van protoplasten uit beide uitgangsweefsels tot microcalli en zgn. groen callus bleek zeer eenvoudig. De verdere uitgroei tot planten kon niet gerealiseerd worden, heel incidenteel werden wortels verkregen (Hoofdstuk 3).
In Hoofdstuk 4 wordt een, voor cassave, nieuwe vorm van embryogene callus- en suspensie-cultuur geïntroduceerd. Deze 'friable' callus- en suspensies-cultures waren afkomstig van Dr. N. Taylor van de Universiteit van Bath in Engeland. Van dit systeem was bekend dat het nieuwe embryos vanuit de buitenste cellaag van de pro-embryos en vanuit één enkele cel vormde. Deze celsuspensie was in de praktijk een zeer goede bron voor protoplasten. Het bleek mogelijk de protoplasten afkomstig van deze suspensies tot micro-callus en callus te laten opgroeien, gebruikmakend van de ontwikkelde media en methoden beschreven in Hoofdstuk 3. Het callus was ten dele 'friable' en kon betrekkelijk eenvoudig tot de productie van volwassen embryos geinduceerd worden of kon prolifereren tot een nieuwe embryogene suspensie. Uitgaande van de volwassen embryos was het tenslotte mogelijk om scheuten te verkrijgen. Dertig procent van de volwassen embryos groeide uit tot planten.
Het gebruik van deze embryogene suspensies in transformatie experimenten door middel van 'partiele bombardment' (het beschieten van suspensies met kogeltjes die bedekt zijn met DNA dat - eenmaal in de plant aanwezig- aanleiding geeft tot de productie van licht) wordt in Hoofdstuk 5 beschreven. Het markergen dat zorgt voor de emissie van licht, het zgn. Lucife-rase gen afkomstig uit het vuurvliegje, werd hier als selectiemarker gebruikt om transgene embryogene suspensies te verkrijgen. Herhaalde selectie van transgeen callus, gebaseerd op de emissie van licht, resulteerde in cultures waarvan een gedeelte op grond van de expressie van het luciferase gen transgeen was. Bij één experiment werd geprobeerd om de suspensies uit te laten groeien tot volwassen embryos. Dit lukte met een zeer lage efficiëntie. De getransformeerde embryos werden daarna eerst d.m.v. secundaire embryogenese vermeerderd. Een klein aantal van de volwassen embryos groeide tenslotte uit tot scheuten. Deze scheuten bleken ook, op grond van hun Luciferase activiteit, transgeen te zijn. Dit werd door moleculaire analyses m.b.v. PCR en Southern hybridisatie van zowel embryogene cultures als scheuten bevestigd. De scheuten bleken ten minste vier inserten van het ingebrachte construct te bevatten. De methode lijkt bij het cassave genotype TMS 60444 reproduceerbaar, maar met een lage frequentie, te werken. Verder onderzoek zal erop gericht zijn de methode toepasbaar te maken voor meerdere genotypen, terwijl ook getracht zal worden de efficiëntie te verhogen. Belangrijke 'bottle-necks' zijn maturatie van embryos uit de embryogene suspensies en scheutvorming van de volwassen embryos.
In Hoofdstuk 6 zijn resultaten beschreven van experimenten die erop gericht waren de scheut-
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conversie te verhogen. Het bleek dat het uitdrogen van NAA geïnduceerde embryos leidde tot een snellere en hogere frequentie van scheurvorming. Uitdrogen van 2,4-D geïnduceerde embryos gaf dit effect niet. Het was noodzakelijk om cytokinine (BAP) aan de kiemingsmedia toe te voegen. De morfologie van de verkregen scheuten was sterk afhankelijk van de gebruikte BAP concentratie. Wanneer de concentratie van BAP laag was (ca 0.1 mg/l) gaf dit aanleiding tot enkelvoudige scheuten per embryo. Was de concentratie hoog (ca 1.5 mg/l of meer) dan bleken er zich per embryo meerdere scheuten te ontwikkelen. Meer onderzoek is nodig om de scheutconversie bij de embryogene suspensie cultures te verbeteren.
Dit proefschrift heeft een belangrijke bijdrage geleverd aan de ontwikkeling van een transformatieprotocol voor cassave. Deze transformatie methode is op het moment ontwikkeld voor één bepaald genotype. Het succesvol induceren van een embryogene suspensie cultuur bij andere cassave genotypen zal ook hier de weg tot transformatie openen. Echter het feit dat vanuit deze embryogene suspensies protoplasten te isoleren zijn die in staat zijn verder tot scheuten te ontwikkelen opent alternatieve wegen voor transformatie. Door protoplasten in combinatie met Agrobacterium cocultivatie, electroporatie of polyethyleen glycol (PEG) gemedieerde DNA overdracht toe te passen wordt enerzijds de efficiëntie aanmerkelijk verhoogd terwijl anderzijds de kans op chimerie, die bij partiele bombardment van de embryogene suspensies groot is, verwaarloosbaar klein. De hier beschreven transformatie methode brengt de veredeling van cassave met behulp van transgenen dichterbij.
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RINGKASAN
Ubi kayu (Manihot esculenta Crantz) adaiah tuberina yang tumbuh di daerah tropik serta mempunyai kegunaan yang unik. Ubi kayu adaiah tanaman penghasil karbohidrat utama pada lahan yang marginal atau pada lahan yang pemeliharaannya minimum. Sampai pertengahan tahun 1960 ubi kayu masih merupkan makanan cadangan bagi masyarakat pedesaan di beberapa propinsi terutama di Jawa. Sekarang ubi kayu terutama digunakan sebagai tanaman pengganti jika tanaman utama gagal dipanen. Budidaya ubi kayu terutama ditujukan untuk industri tepung tapioka dan pakan ternak. Selain untuk bahan baku industri, ubi kayu yang berkadar HCN rendah dikonsumsi sebagai makanan penganan. Teknologi pengolahan lanjut karbohidart dari ubi kayu seperti untuk sirup glukosa dan monosodium glutamat di luar negeri, antara lain di Muangthai telah dimulai sejak tahun 1950. Kegunaan ubi kayu di bidang industri akhir-akhir ini semakin meningkat, di Jepang terutama dipakai untuk industri sirup dekstrosa, industri makanan, industri kertas dan industri kimia. Di Nigeria penelitian mengenai ubi kayu diarahkan untuk menghasilkan tapioka yang bisa dijadikan bahan pencampur tepung terigu menjadi "tepung komposit" untuk membuat roti. Program tepung komposit di beberapa negara berkembang di Afrika seperti di Nigeria, Uganda dan Zaire telah dimulai sejak tahun 1964, dengan tujuan mengurangi import tepung terigu yang mahal sehingga mampu menghemat keuangan negara. Dalam dekade ini industri makanan yang menggunakan tepung terigu sebagai bahan bakunya meningkat pesat di Indonesia. Jika rasio amilose-amilopektin dalam tepung tapioka dapat dimodifikasi maka penggunaan tepung terigu dapat dikurangi. Substitusi parsial tepung terigu dengan tepung tapioka yang dimodifikasi akan mengurangi impor gandum. Rekayasa genetik untuk merubah ratio amilose-amilopektin pada ubi kayu peluangnya terbuka dan menjadi kajian beberapa industriawan di negara anggota Masyarakat Ekonomi Eropa dan Anerika Serikat.
Agroindustri memerlukan kultivar yang cocok terutama untuk produksi tepung tapioka. Program pemuliaan ubi kayu pada tingkat internasional telah mengantisipasi tuntutan kebutuhan pasar yang situasional dengan teknologi DNA. Gen yang dikehendaki dapat di-transfer ke dalam genom dengan transformasi genetik. Transformasi gen perlu sebuah sistem regenerasi yang efisien dan dapat dibakukan. Beberapa sistem regenerasi pada ubi kayu melalui somatik embriogenesis yang diinduksi dengan auxin telah dikembangkan. Dalam sistem tersebut embryogenesis bisa dilakukan secara berulang-ulang sehingga merupakan siklus (embriogenesis sekunder).
Beberapa usaha untuk membuat sistem transformasi yang bisa dibakukan pada ubi kayu dengan menggunakan somatik embrio serta Agrobacterium tumefaciens sebagai mediatornya ternyata belum berhasil. Penggunaan bom partikel dengan target embrio matang juga tidak
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berhasil mendapatkan transformasi gen yang stabil. Hasil maksimal dengan cara ini hanya embrio yang kimerik, berarti hanya sebagian kecil sel yang mengalami trasnformasi. Kimerik ini bisa dihindari jika regenerasi tanaman melalui protoplas berhasil. Oleh karena itu target pertama dari penelitian ini adalah mengembangkan sistem somatik embriogenesis dan regenerasi protoplas yang bisa dipakai target transformasi gen.
Dalam Bab 2 dikemukan bahwa NAA mampu menginduksi somatik embriogenesis sekunder, tapi tidak untuk induksi primer. Induksi embriogenesis dengan NAA ternyata lebih responsif dan produktif serta waktu yang diperlukan lebih singkat dibanding dengan induksi dengan 2,4-D. Tapi frekuensi siklus embriogenesis yang tinggi seperti di atas lima siklus, induksi NAA ini dapat menyebabkan embrio berakar (adventitious root), pada 2,4-D fenomenon ini tidak dijumpai.
Induksi embriogenesis sekunder dengan NAA hampir bersifat genotipe independen, semua genotipe yang diuji bisa memproduksi embrio. Populasi eksplant yang tinggi atau memperpendek siklus kultur, cenderung menghasilkan embrio yang premature, baru berkembang menjadi embrio matang jika ditransfer ke medium MS ditambah 0.1 mg/l BAP. Pada prinsipnya somatik embrio adalah klon, sehingga dapat dipakai untuk perbanyakan bibit secara masal.
Penelitian protoplas pada ubi kayu umumnya menggunakan daun muda atau batang sebagai donor protoplas. Dalam Bab 3 disajikan hasil penelitian dengan menggunakan mesofil daun dan somatik embrio sebagai donor protoplas. Beberapa komposisi pengatur tumbuh dicoba pada berbagai stadia perkembangan protoplas, ternyata tidak berhasil menginduksi regenerasi tanaman. Kalus yang berwarna hijau dan kadang-kadang berakar dapat diinduksi, baik dari mesofil daun maupun dari somatik embrio. Induksi akar berhubungan dengan adanya NAA pada medium A (induksi pembelahan sel). Kegagalan regenerasi diduga akibat inkompetensi protoplas atau komposisi media tidak tepat atau akibat kombinasi keduanya.
Sistem somatik embriogenesis yang paling baru telah diketemukan yaitu kalus embriogenik
remah (friable embryogénie callus=FEC). System ini berbeda dengan somatik embriogenesis
yang menggunakan eksplant berasal dari jaringan yang telah berdeferensiasi dan mengalami organogenesis. FEC bentuknya selalu "pre-globular embryo" berdiameter maksimal 1 mm, tingkat proliferasinya tinggi serta berasal dari lapisan permukaan sel.
Upaya untuk memperoleh system regenerasi tanaman dari protoplas diulang dengan mengunakan FEC sebagai donor protoplas. Metoda isolasi dan kultur protoplas dalam Bab 3 diaplikasikan lagi pada FEC (Bab 4). Perubahan hanya pada media pertama yaitu
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menggunakan medium TM2G. Kultur protoplas tahap pertama dalam medium TM2G perlu waktu 3 sampai 4 minggu untuk pembelahan sel dan induksi mikro kalus, seterusnya setelah dikulturkan selama dua bulan, protoplast berkembang menjadi FEC dengan kualitas yang tinggi. Setelah ditransfer ke media MS yang dimodifikasi (medium pematangan), FEC tumbuh menjadi embrio.
Perbanyakan FEC dilakukan dengan pertama dikulturkan pada media Gresshoff dan Doy 4%
(GD4) + 2 mg/l Picloram selama 21 hari, seterusnya transfer ke GD2 + 10 mg/l Picloram. Kualitas FEC yang baik bisa dipakai untuk inisiasi kultur suspensi sel. Induksi tunas dilakukan dengan cara mengkulturkan embrio pada medium MS2 + 1 mg/l BAP. Tunas akan tumbuh setelah dikulturkan minimal selama empat minggu.
FEC adalah proembrio yang tumbuh dari sel tunggal di permukaan embrio yang telah ada, jadi dia merupakan "daughter cell" dari proembrio, oleh karena itu cocok untuk dijadikan target transfer gen dengan bom partikel. Genotipe TMS60444 dibom dengan plasmid
konstruksi pJitlOO atau pJit64 yang mengandung gen Luciferase berasal dari serangga Kunang-kunang (Bab 5). Parameter-parameter seperti jarak sel target, momentum peluru pembawa DNA ternyata tidak determinatif. Kualitas bahan awal (FEC) lebih menentukan keberhasilan transformasi gen. Oleh karena itu perhatian harus diutamakan agar kultur FEC dengan kualitas yang prima dapat dicapai. Kultur FEC selama 6 minggu pada medium cair SH6 berpengaruh positif untuk transformasi transien, tapi untuk transformasi LUC yang stabil pengaruhnya tidak konsisten.
Seleksi FEC yang telah mengalami transformasi ("transformant") baik yang transien maupun stabil dilakukan dengan mengukur aktifitas gen luciferase (LUC). Aktivasi gen LUC oleh luciferin pada sel mengakibatkan transmisi sejumlah photon yang dapat dimonitor dengan camera CD super sensitive VIM dan diproses dengan penghitung citra Argus-50 bikinan Hamamatsu Phototonic Systems. Embrio yang positif mengandung LUC dikulturkan dalam medium cair atau padat SH6 + 10 mg/l Picloram. Dalam waktu 8 minggu "transformant" FEC yang dikulturkan dalam medium cair meningkat hampir lima kali sedangkan dalam medium padat tiga kali.
Sebelum induksi tunas, embrio "transformant" yang telah matang diperbanyak dengan cara somatik embriogenesis seperti diuraikan pada Bab 2. Embrio menjadi matang (hypocotil dan cotyledon nampak jelas) setelah dikulturkan dalam medium MS yang dimodifikasi. Analisa molekul untuk mengetahui status transgenik tanaman, yaitu dengan PCR menggunakan primer yang mengandung luciferase (LUC1 dan LUC2), serta Southern Blot Analysis menggunakan EcoRV atau BglII sebagai enzym pemotong DNA.
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Pada Bab 6 daya kecambah embrio yang diinduksi dengan NAA dan 2,4-D dibandingkan. Dengan metoda desikasi ternyata embrio yang diinduksi NAA berkecambah lebih tinggi dari embrio yang diinduksi 2,4-D. Agar embrio berdaya kecambah tinggi diperlukan cytokinin. Konsentrasi cytokinin rendah (0.1 mg/1 BAP), dan diinkubasikan dalam ruang gelap hasilnya setara dengan konsentrasi tinggi (1 mg/1 BAP) dan dikulturkan di tempat terang. Tapi morfologi tunas dan waktu berkecambah dari kedua lingkungan di atas berbeda.
Thesis ini merupakan sebuah terobosan utama dalam mebuat cara-cara transformassi gen yang bisa dibakukan melaui bom partikel pada ubi kayu. Seterusnya juga akan membuka alternatif untuk transformasi gen dengan menggunakan regenerasi protoplas melaui elektroporasi dan PEG.
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Curriculum vitae
Eri Sofiari (Abullah Faqih), has no original date of birth that has ever been recorded. He was born during an fierce civil war in the middle of 1950s in a remote area of Tasikmalaya, West Java, Indonesia. He registered for The Primary School at Garut in 1959 and completed in 1963. Finally, he has an official date of birth of 1 May, 1950 given by his School Master.
The academic study started in 1971 at Tanjungsari Academy of Agriculture and he got the B.Sc degree in Farming Systems in 1974. He worked at Lembang Research Institute for Horticulture (LEHRI), Bandung, since 1974. First he joined the Seed Technology Group in ATA (Assistance Technical Agriculture) project 111 from the Netherlands, in the sub section of Plant Breeding, from 1974 until 1980. In 1982 he completed the degree of Stratum one (SI) in Agronomy from University of Padjadjaran, Bandung. From 1982 until 1985 he was a coordinator for the production of breeder and extension seed for the National Vegetables Seed Production, and as a seed inspector for Seed Potato Production Project. In 1985 he continued the study of stratum two (S2) programme at the Graduate School, University of Padjadjaran, and finished in 1987. From 1988 until 1991 he joined the Hot Pepper Research Group as a coordinator, and as a researcher in a programme of breeding for resistance to Anthracnose on Hot Pepper under the Project of ATA 139 financed by The Netherlands.
In April 1991 he attended the School of Plant Sciences at Reading University registered as an ad-hoc student for PhD programme in inter and intraspecific hybridization in Capsicum
spp. with Dr. Barbara Pikergills. In September 1992 he decided to changed the study and moved to Wageningen Agricultural University. Since then, he has carried out the research programme on this thesis at the Cell Biology Laboratory of the Department of Plant Breeding under the supervision of Prof. Dr. Ir. E. Jacobsen and Dr. R.G.F. Visser.
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ACKNOWLEDGEMENTS
In the name of God, The Most Beneficent, The Most Merciful
Praise be to God, The Lord of the universe, and peace be upon the Master of Apostles his family and companions. To Him , The Possessor of Power and Authority, The Opener of Doors of Success For Mankind, The Lord Almighty I prostrate in thanks and submission. I surrender to You and trust You in all my affairs and depend upon You for Your Blessing both with hope and fear of You.
I am sure, this thesis could not have been achieved without the help of Him, through His mercy the numerous persons were willing to support me.
I am greatly indebted to the Agency for Agricultural Research and Development (AARD)/Ba-dan Penelitian dan Pengembangan Pertanian, Jakarta, Indonesia; Central Research Institute for Horticulture, Jakarta (CRIH) and Research Institute for Vegetable, Lembang-Bandung, formerly Lembang Horticultural Research Institute (LEHRI), Agriculture Research Management Project (ARMP), Bogor who sponsored my study at Wageningen Agricultural University.
I would like to thank particularly Dr. Sutatwo Hadiwigeno (Former Director of AARD), Dr. Faisal Kasryno (Director of AARD), Mrs. Paransih Isbagyo MSc (Former Secretary of AARD), Dr. Farid Bahar (Former Director CRIH), Dr. Prabowo Tjitropranoto (Director CRIH), Dr. Aziz Azirin (Former Director of LEHRI), Dr. Ati Sri Duriat (Director of Research Institute for Vegetable), and Prof. Dr. Ahmad Baihaki (Professor in Plant Breeding, Padjadjaran University, Bandung) and Dr. Sumpeno Putro (Former Leader of ARMP).
My gratitude and acknowledgements are to my promotor Prof. E. Jacobsen and co-promotor Dr. R.G.F. Visser. Both participated intensively in advising and directing me to complete the thesis. Their supervision was highly inspiring, and most helpful to gain experience and insight in this field of study. They showed much concern, helped solve my financial problems at the end of my study and devoted many hours of their leisure hours correcting, criticizing the content of my thesis. I cannot find the better words to thank both of you, particularly Dr. Visser who provided the ticket for my wife to come to Wageningen.
I am grateful to Dr. C.J.J.M. Raemakers for the tremendous amount of assistance I have received from him. He is the third promotor of my thesis. He was a constant source of inspiration, encouragement and guidance throughout the conduct of the research and the final
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writing of this thesis. He almost never said 'no' when I asked him for help.
Prof. Jacobsen, Dr. Visser and Dr. Raemakers are good discussion partners and I learned from them to analyze problems, to draw conclusions and to develop new ideas. I will never forget their support.
It is pleasure for me to thank to :
- Miss Glenna Howell and staff of Winrock International at Arkansas, USA; Dr. Henk
Knipscheer (Winrock International, Indonesia), for administrating the funds of this study.
- Miss Ing. Marjan Bergervoet, who taught me how to handle protoplasts and assisted me in the tissue culture work. The assistance of her is greatly appriciated. I learned a lot during the four years of work in the cell biology lab with her and other colleagues.
- Elly Janssen and colleagues at the molecular lab for helping and assisting me in PCR and
Southern Blot Analysis.
- Dr. G.A.M. van Marrewijk, who introduced me to Prof. Jacobsen and gave useful advice during my study period in Wageningen.
- Dr. M.S. Ramanna for correcting the English text of this thesis.
Wageningen, particularly the Agricultural University, is the place to which my heart is tightly bound. There are so many people who participated and helped me with this study. From Mr. Henk Sengers with whom I used to speak terribly broken Dutch when he came into the lab in the evening to check if doors were locked properly, to Dr. A.M. van Harten, who provided me with a nice room and other facilities at the Department of Plant Breeding. I am not able to mention them one by one. I sincerely appreciate their support.
Special thanks are due to my mother, Siti Djuwariyah, she is the Great Woman in my life to whom I am privilaged to offer good care. She let me go to study abroad for a long time. I am really indebted to her. Hopefully she will be proud of my achievement.
Last but not least, I would like to extend special thanks to my dear wife Ati (Tati Kurnianti Hamid) for her prayers, patience and encouragement during the very long period of separation we have gone trough. May God bountifully bless her.
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